Mixed fuel coal burner for gas turbine engines

ABSTRACT

As shown schematically in FIG.  1 , hot gases, containing oxygen, from generator elements, ( 14 ) and ( 19 ), pass through a bed of coal chunks in an ODD reactor, ( 2 ). The oxygen content of these hot gases is less than stoichiometric, relative to the coal volatile matter content, so that partial oxidation of only the volatile matter occurs within the ODD reactor ( 2 ), during devolatilization therein. Two products are thusly created, a partially oxidized, and hence cleaner burning, volatile matter fuel gas, and a solid devolatilized coke. The hot coke is transferred, by overfeed, into a coke reactor, ( 7 ), where counterflowing primary air, via air meter, ( 12 ), gasifies the coke into carbon monoxide with some carbon dioxide. Finally, the carbon monoxide and the partially oxidized volatile matter, are admixed with overfire air, and burned fully to carbon dioxide in overfire burners, ( 23 ), ( 26 ). The resulting hot burned gases flow into the nozzle inlet, where, after mixing with bypass air, they expand through the expander portion of a gas turbine engine. Coal ashes accumulate at the bottom, ( 9 ), of the coke reactor, ( 7 ), where the overlying coal chunks prevent ash particle carryover into the turbine blades. Low cost coal can thus be cleanly used as an energy source for gas turbine engines.

BACKGROUND OF THE INVENTION

This invention is in the technical field of coal burners for furnaces and gas turbine engines.

Prior efforts to burn coal in gas turbine engines, such as by use of pulverized coal, or coal in water slurries, have been unsatisfactory due to turbine blade maintenance problems, caused by coal ash particles being carried into the turbine blades, with the hot gases flowing therethrough.

As a result, gas turbine engines, such as are used for electric power generation in combined cycle plants, today burn natural gas, or petroleum distillate fuels, and these fuels are increasingly in short supply, and thus expensive.

As of October 2004, coal cost is about one-fifth of natural gas cost, per unit of energy. Known coal reserves are much greater than known petroleum and natural gas reserves, both nationally, and internationally.

SUMMARY OF THE INVENTION

In a mixed fuel coal burner of this invention, coal chunks pass through two separate reaction chambers in series. In the first, ODD, reaction chamber the coal is heated by a throughflow of hot gas, containing some oxygen, in order to carry out oxidative destructive distillation, ODD, of the coal volatile matter. The oxygen content of these hot gases is less than stoichiometric, relative to the coal volatile matter, so that partial oxidation of only the volatile matter occurs in the ODD reactor. Two fuel products thus emerge from the ODD reactor, a devolatilized coke product, which is passed into the second coke reactor, and a partially oxidized coal volatile matter gas. The partially oxidized coal volatile matter gas is mixed with an overfire air, and fully burned, in an ODD overfire burner, and the resulting burned gases pass into the turbine. Partially oxidized volatile matter can thus be burned cleanly in the ODD overfire burner, with greatly reduced creation of undesirable soot or tar, and this is one of the beneficial objects of this invention.

The devolatilized coal chunks are delivered, by overfeed, into the top, or gas exit end of a bed of hot burning coke, in the second coke reactor. Primary air flows upward through the coke reactor and countercurrent to the coal chunk flow direction. The coke reacts rapidly with oxygen in the counterflowing primary air, and the resulting very hot burned gases quickly heat up entering coke chunks by connective heat transfer. The coke is thus burned up rapidly, and completely, to carbon monoxide and carbon dioxide while passing through coke reactor. This coke burn rate is proportional to the rate of supply of primary air into the coke reactor. Thus the power output of a gas burning engine, using this coal burner, can be controlled by control of the primary air flow rate into the coke reactor over a very wide range of engine power output, and corresponding coal burn rates.

The exit gases from the second coke reactor are rich in carbon monoxide fuel, and these are mixed with additional overfire air, and burned fully to carbon dioxide, in a carbon monoxide overfire burner, and these fully burned gases flow into the turbine inlet nozzles.

Prior art underfeed coal burners used a single reaction chamber to achieve similar clean burning of high volatile matter bituminous coals. With these underfeed burners, the coal and primary air moved in the same direction through the reactor. As a result, the fresh coal volatile matter evaporates into the oxygen rich incoming primary air. In this way the evaporating volatile matter receives the partial oxidation, needed for clean burning thereof, without soot and tar formation. But the entering coal chunks are heated up to rapid burning temperatures, by slow radiation heat transfer between chunks, and not by rapid convective heat transfer from hot burned gases. This radiation heat transfer rate, and hence the coal burn rate, is not only slow, but cannot be controlled by control of the primary air flow rate, as is needed for control of the power output of a gas turbine engine.

This is another beneficial object of this invention, over the prior art, that high volatile matter bituminous coals can be burned cleanly, at a high burn rate, and that this burn rate can be controlled, over a wide range, by control of the rate of flow of primary air into the second coke reactor.

With overfeed supply of coal chunks into the coke reactor final coke burnup to ashes occurs at the bottom of the second coke reactor, and the ash particles, which are smaller than the coal chunks, are restrained from being blown out of the coke reactor, and into the gas turbine engine, by the overlying coke bed. With prior art, underfeed coal burners, the small ash particles are formed at the top of the fuel bed, and can thus be blown out of the fuel bed, and into the gas turbine engine, resulting in turbine blade damage.

It has been this carryover of ash particles, into the gas turbine engine, and resulting turbine blade damage, which has previously prevented the use of low cost, and readily available, coal fuels in gas turbine engines. At present, gas turbine engines, such as are widely used in combined cycle electric power generating plants, operate only on expensive natural gas, or petroleum distillate fuels. This is a principal beneficial objet of this invention, that low cost, ash containing, coals can be cleanly burned, in a gas turbine engine, without ash carryover into the turbine blades.

A mixed fuel coal burner of this invention can additionally comprise a supplementary fuel air mixture overfire burner, which burns a gas or liquid fuel, such as natural gas, in the overfire space, above the coke fuel bed. This supplementary fuel burner can be used to control gas turbine engine speed very closely, as such burners can respond quickly to speed changes. The coal burner, while readily governable, responds slowly to speed changes, whereas in most applications, such as electric power generation, very close speed control is needed.

This supplementary fuel air mixture overfire burner also provides a method for adjusting the relative fuel quantities being used by the gas turbine engine, and these quantities can then be changed, in response to changes in fuel prices and availability.

BRIEF DESCRIPTION OF THE DRAWINGS

A schematic diagram of an example form of mixed fuel coal burner, of this invention, is shown in FIG. 1.

In FIG. 2 an example controller, for controlling a mixed fuel burner of this invention, is shown schematically for use on a gas turbine engine.

Additional related controls are shown schematically on FIG. 3.

The preferred operating regions, for the ODD reactor portion, of a mixed fuel coal burner of this invention, are shown graphically in FIG. 4.

The preferred operation regions for the coke reactor portion, of a mixed fuel coal burner of this invention, are shown graphically in FIG. 5.

The operating characteristics of an example generator of hot oxygen containing gases is shown graphically on FIG. 6.

An example refuel mechanism for use on a mixed fuel coal burner is shown schematically in FIGS. 7 and 8. FIG. 8 is the cross section, A-A, of FIG. 7. FIG. 7 is the cross section, B-B, of FIG. 8.

An example gas manifold and inlet ports system for admitting hot oxygen containing gases into an ODD reaction chamber is shown in cross section in FIG. 9.

The effects of coal chunk size, and fragmentation, on chunk lift off limited air mass velocities, through the ODD reactor, and coke reactor, are shown graphically on FIG. 10.

An example air manifold and inlet ports system for admitting primary air into the coke reactor is shown in cross section in FIG. 11.

None of the apparatus drawings are to scale.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

One example form of a mixed fuel coal burner of this invention is shown schematically in FIG. 1, as adapted for use with a gas turbine engine, and comprises the following elements:

-   1. The oxidative, destructive distillation, ODD, reactor, 1,     comprises an ODD reaction chamber, 2, and a refuel mechanism and     driver, 3. The refuel mechanism can transfer coal chunks,     periodically, from an external coal supply source, at atmospheric     pressure, not shown, sealably into the pressurized lower refuel end,     4, of the ODD reaction chamber, 2. The refuel mechanism, 3,     functions thusly to keep the ODD reaction chamber, 2, essentially     full of coal undergoing oxidative destructive distillation. Excess     coal, reacted to coke, spills out of the upper gas outlet end of the     ODD reactor, 2, at each refueling, into the upper end, 5, of the     coke reactor, 6, which utilizes overfeed coke fuel delivery. -   2. A portion of the gas turbine engine compressor discharge air is     delivered into an ODD reaction burner, 14, via the positive     displacement air supply meter, 15, from the compressor air pipe, 13,     and is admixed therein with a gaseous fuel, such as natural gas,     delivered under adequate pressure, from a source, 16, via the     positive displacement air supply meter, 17. The resulting     essentially stoichiometric fuel air mixture is ignited, as by a     spark, 18, and burns within the ODD burner, 14. The resulting very     hot burned gases pass into the ODD mixer, 19, and therein, are     admixed with another mixer portion of gas turbine engine compressor     discharge air, delivered from the compressor air pipe, 13, via the     positive displacement air supply meter, 20. The resulting hot mixed     gases, containing some oxygen, are delivered into the lower end of     the ODD reaction chamber, 2, via a manifold, 21, and move through     the coal chunks therein, upward in the same general direction as the     direction of coal movement.

The hot oxygen containing mixer exit gases are ideally admitted uniformly over the ODD reactor cross sectional area. But this uniform admission would require a flow of these hot gases through the refuel mechanism, 3, with resulting maintenance problems on the refuel mechanism. A compromise plan is to admit the hot mixer exit gases peripherally into the ODD reaction chamber, 2, via several ports, 101, distributed peripherally around the chamber, from a supply manifold, 102, as illustrated in FIG. 9. These gas admission ports, 101, are preferably somewhat above the refuel mechanism, 3, by at least one refuel package, 103, in order to insulate the refuel mechanism, 3, from the hot mixer exit gases flowing through the ODD reaction chamber.

With peripheral admission of hot mixer exit gas, into the ODD reactor, as illustrated in FIG. 9, coal chunks, in the reactor center, will receive mixer exit gas partially oxygen depleted by flow through outer coal chunks. This could result in a possible increased yield of soot and tar from these central coal chunks. This effect becomes aggravated as ODD reactor cross section area is increased. By using two or more ODD reaction chambers, 2, for each coke reactor, 7, the area of each ODD reactor can be reduced, and the formation of soot and tar reduced.

-   3. The coal chunks in the ODD reactor are heated up, by direct     contact convective heat transfer, from the hot mixer exit gases     passing through, to temperatures where rapid distillation of the     coal volatile matter occurs. At coal temperatures above 1500°R., the     coal also undergoes a complex thermal cracking process of     destructive distillation. Such destructive distillation, in the     presence of less than stoichiometric oxygen relative to the created     volatile matter, leads to partially oxidized gaseous volatile matter     products. These partially oxidized volatile matter fuels, when     subsequently burned with added overfire air, burn cleanly, with     little or no formation of soot or tar.

For the purposes of this invention, the flow rate of oxygen, into the ODD reactor, 2, via the hot mixer exit gas, is to be less than stoichiometric, relative to the flow rate of coal volatile matter, into the ODD reactor, 2, via the refuel mechanism, 3. Details for achieving this result are described hereinbelow in the ODD reactor sizing section.

But volatile matter molecules, not thusly partially preoxidized, are known to create soot and tar when burned. This is one of the beneficial objects of this invention, that coals, containing appreciable volatile matter, such as bituminous coals, can be burned cleanly, with little or no formation of soot or tars, by applying this oxidative destructive distillation, ODD, process to the coal chunks within the ODD reactor chamber.

-   4. Prior art, underfeed stoker, coal burners achieved similar     essentially soot and tar-free burning, of high volatile matter     bituminous coals, by use of essentially this same oxidative     destructive distillation process, achieved by use of underfeed     stokers. With underfeed stokers, coal and primary air flow in the     same direction, within the burning fuel bed, thus assuring that the     needed oxygen is present, at the start of the burning zone where     destructive distillation of volatile matter is taking place. But,     with underfeed stokers, the burning zone advances into fresh coal by     radiation and solid interchunk conduction of heat, and this heat     transfer rate is not only slow, but largely independent of the rate     of supply of primary air, into the fuel bed. As a result, the rate     of coal burning cannot be controlled by control of primary air flow     into the fuel bed. For gas turbine engines, the engine power output,     and speed, need to be closely and quickly controllable, by control     of the fuel burning rate, and hence by control of the rate of flow     of a portion of the compressor discharge air into the coal burner.     This is another of the beneficial objects of this invention, that     the rate of oxidative destructive distillation of bituminous coals,     can be controlled by control of the flow of hot oxygen containing     mixed gases into the ODD reactor. Therein heat transfer, between     these hot mixed gases and the coal chunks, is convective, and thus     increases as gas flow rate increases, and is thus controllable. -   5. As shown in FIG. 1, the ODD reactor, 1, can be inclined, so that     the coal chunks fully occupy the cross section of reaction chamber,     2, thus assuming that mixer gas cannot bypass the coal fuel bed. At     large angles of ODD reaction inclination from the horizontal, a     transfer mechanism can be used to forcibly transfer devolatilized     coke chunks, from the ODD reactor upper gas exit, into the upper gas     outlet end, 5, of the coke reactor, 6. -   6. The gases flowing out of the exit end, 22, of the ODD reactor, 2,     and comprising partially oxidized volatile matter products of     destructive distillation, enter the ODD overfire burner, 23. Another     portion of the compressor discharge air is delivered into this ODD     overfire burn zone, 23, via the positive displacement air supply     meter, 24, and mixes with these partially oxidized volatile matter     products, to create an ignitable and burnable fuel air mixture. This     fuel air mixture can be ignited by various means, such as by the hot     devolatilized coke at the ODD reaction chamber exit, 22, and at the     upper end, 5, of the coke reactor, 6. -   7. Other fluids, such as very highly superheated steam, to which     some air or other oxygen source has been added, can be substituted     for the ODD burner, 14, and mixer, 19, scheme, for creating a hot     oxygen containing gas, for heating the coal in the ODD reactor. -   8. The coke reactor, 6, comprises a coke reaction chamber, 7, and an     ash removal mechanism and driver, 8. The ash removal mechanism, 8,     can transfer ashes, periodically, from the bottom ash removal end,     9, of the coke reactor, 6, at pressure, sealably into an external     ash receiver, at atmospheric pressure, not shown. The ash removal     mechanism, 8, functions thusly to remove ashes from the coke     reactor, 6, while keeping a protective ash layer, 10, always present     between the hot burning coke in the oxygen burn zone, 11, and the     ash removal mechanism, 8. The refuel mechanism, 3, is controlled to     transfer coal, into the ODD reactor, 1, at a sufficient rate, that     the spillover of ODD reacted coke, into the coke reactor, 6, keeps     the coke reaction chamber essentially full of coke chunks undergoing     reaction with primary air. A portion of the gas turbine engine     compressor discharge air is delivered into the coke reactor, 6, via     the positive displacement air supply meter, 12, from the compressor     airpipe, 13, and supplies the primary air, which flows through the     coke reaction chamber, 7, in a direction countercurrent to the     direction of coke movement The coke reactor, 6, is thus similar to     an overfeed stoker.

The primary air is preferably admitted peripherally into the coke reaction chamber, 7, at several points, 104, distributed peripherally around the chamber from a supply manifold, 105, as shown in FIG. 11. These primary air admission points, 104, are preferably somewhat above the ash removal mechanism, 8, so that the high temperature oxygen burn zone, 11, is separated from the ash removal mechanism, by an insulating layer of ash, 9, located just below the admission points, 104.

If coals which tend to form klinkers are to be used, the coke reaction chamber can be tapered, as shown in FIG. 11, with the cross section area increasing in the direction of coke motion. In this way, downward motion of the coal chunks may not be impeded by klinkers.

With peripheral admission of primary air into the coke reactor as illustrated in FIG. 11, centrally located coal chunks will receive air partially depleted of oxygen by flow through outer coal chunks. These central coal chunks may thus react more slowly than the outer coal chunks and this effect is aggravated as coke reactor cross sectional area is increased. This uneven reaction of coke can be minimized by using two or more coke reaction chambers.

-   9. The devolatilized coke is delivered into the coke reaction     chamber, 7, from the ODD reactor, 1, at a high temperature, well     above the coke rapid reaction temperature with air. Rapid reaction     of the oxygen, in the throughflowing compressor discharge air     portion, with the hot coke surface thus occurs, creating an oxygen     burn zone, 11, in the coke reactor, whose principal gas product is     carbon dioxide. During startup, this oxygen burn zone advances     toward the incoming air, and becomes essentially stationary, on top     of the protective ash layer, 10. The available oxygen is almost     completely reacted, and largely to carbon dioxide, in this rather     thin oxygen burn zone. A carbon dioxide burn zone, 25, is created in     the upper portions of the coke fuel bed, where carbon dioxide gases     react with the hot coke surface, to form carbon monoxide gases. This     reaction of carbon dioxide, with the hot coke surface in the carbon     dioxide burn zone, 25, is appreciably slower than the reaction of     oxygen with the hot coke surface in the oxygen burn zone, 11, and a     thicker carbon dioxide burn zone is required, in order to achieve     appreciable depletion of the carbon dioxide by this surface reaction     to form carbon monoxide.     With an adequately deep carbon dioxide burn zone, 25, gases exit     from the coke fuel bed via the upper gas outlet end, rich in carbon     monoxide, with mol fractions thereof approaching 0.40, and enter the     carbon monoxide overfire burn zone, 26. -   10. Another portion of the compressor discharge air is delivered     into this carbon monoxide overfire burn zone, 26, via the positive     displacement air supply meter, 27, and mixes therein, with the exit     gases from the coke fuel bed, to form an ignitable and burnable fuel     air mixture. This carbon monoxide fuel air mixture can be ignited by     various means, such as by the hot devolatilized coke at the upper     end, 5, of the coke reactor, 6, or by the adjacent burning fuel air     mixture in the ODD overfire burner zone, 23. To assure ignitability     and burnability of this carbon monoxide fuel air mixture in the     carbon monoxide overfire burn zone, 26, a high carbon monoxide     concentration is preferred in the coke fuel bed exit gases, and this     can be obtained with adequate depth of the coke fuel bed. -   11. As shown in FIG. 1, the ODD overfire burn zone, and the carbon     monoxide overfire burn zone, are contiguous, and could be joined     into a single combined coal gas overfire burn zone, with a single     supply of overfire air. -   12. The fully burned gases, from the ODD overfire burner and the     carbon monoxide overfire burner together with the fully burned gases     from a supplementary overfire burner, if used, are admixed with     those portions of the compressor discharge air, which bypassed the     mixed fuel coal burner, and these combined gases flow into the     expander turbine inlet nozzles, and through the gas turbine engine.     The expander turbine thus functions as a receiver of hot burned     gases.

A mixed fuel coal burner of this invention can alternatively be used in applications other than gas turbine engines, such as boiler furnaces, or process furnaces, where the furnace functions as the receiver of hot burned gases created by the mixed fuel coal burner.

-   13. The rate of burning of the coke chunks, in the coke reaction     chamber, 7, can be fully controlled by control of the rate of supply     of primary air, into the coke reaction chamber, via the positive     displacement air meter, 12, since primary air, and coke, flow in     opposite directions within the coke reaction chamber, which utilizes     overfeed delivery of coke thereinto. With thusly opposed flow     directions, the coke temperature in the carbon dioxide burn zone,     25, is maintained very hot, despite the occurrence of the     endothermic carbon dioxide reaction with the hot coke to form carbon     monoxide, by convective heat transfer from the hot gases, leaving     the exothermic oxygen burn zone, 11, and flowing into the     endothermic carbon dioxide burn zone, 25.

As primary air flow rate is increased, the stagnant gas film on the hot coke surface is reduced in thickness, with a consequent increase of both the heat transfer rate from the hot gases to the surface, and the rate of diffusion of oxygen and carbon dioxide molecules, and hence reaction with, the hot carbon surface. In this way the rate of burning of coke in the coke burner, 7, can be controlled by control of the rate of flow of primary air into the reactor.

With overfeed delivery of coke chunks, into the coke reactor, 7, the coke is gradually gasified, as it descends through the reactor, and final coke burnup to ashes occurs at the bottom of the coke fuel bed. The resulting ash particles are much smaller than the coke chunks, but are nevertheless prevented from being blown through the coke reactor, and into the gas turbine engine nozzles and blades, by the overlying bed of coke chunks. With prior art underfeed burners, this final burnup to ashes occurs at the top, gas exit, end of the fuel bed, and the smaller ash particles can be blown over, through the overfire burner, and into the gas turbine engine, resulting in turbine blade damage.

Prior art efforts to burn coal, in gas turbine engines, using underfeed burners, or pulverized coal burners, have been commercially unsuccessful, due to this ash carryover causing turbine blade damage. It is a principal beneficial object of this invention, that high volatile matter, low cost, bituminous coals, can be cleanly burned, in a gas turbine engine, without ash carryover into the turbine blades.

Primary air is delivered into the gas inlet near the bottom of the coke burner, 7, and flows upward countercurrent to the coke flow direction. The ashes in the ash removal mechanism, 8, and in the protective ash layer, 10, can thus be cooled by the relatively cold incoming primary air. Such cooling, as the ash is emerging from the coke, can function to limit ash particle fusion and agglomeration into klinkers.

-   14. A modified mixed fuel coal reactor of this invention, can be     used to transform coals, containing volatile matter, into two     different fuel products, a clean burning fuel, derived from the coal     volatile matter, and a devolatilized coke fuel, derived from the     coal fixed carbon. The partially oxidized coal volatile matter,     destructively distilled within the ODD reactor together with the     diluents from the hot oxygen containing gas, constitutes the clean     burning fuel, which flows out of the upper gas outlet of the ODD     reactor, and into a receiver or user of such a fuel. The     devolatilized coal chunks, pushed out of the upper gas outlet of the     ODD reactor, and into a coke collector, during refueling,     constitutes the solid coke fuel, which can be utilized elsewhere. -   15. An alternatively modified, mixed fuel coke reactor, of this     invention, utilizes the volatile matter derived fuel as an energy     source for a gas turbine engine. The devolatilized coke fuel is     removed as a byproduct, for use elsewhere, as in iron melting cupola     furnaces, or iron blast furnaces. The devolatilized coke fuel,     transferred out of the ODD reactor chamber, passes into a coke     receiver, at gas turbine air compressor pressure, and is     subsequently sealably transferred, out of the coke receiver chamber,     and into a coke collector, by a coke removal mechanism, functionally     similar to an ash removal mechanism. The volatile matter derived     fuel passes into an ODD overfire burner, as its receiver, and, after     mixing with a supply of ODD overfire air, it is ignited and burned     to hot burned gases. These hot burned gases, from the ODD overfire     burner, flow into the gas turbine inlet, to be admixed with, those     portions of the compressor discharge air which bypassed the mixed     fuel coal burner, plus any other sources of hot gases. -   16. For gas turbine engines driving electric power generators, close     control of engine speed is necessary. For this control purpose, a     supplementary fuel air mixture, and burner may be preferred. Such a     supplementary fuel air mixture system is shown schematically in FIG.     1, and comprises: a source of natural gas, 28, at adequate pressure,     with a positive displacement gas supply meter, 33, a supply of     compressor discharge air, via the positive displacement air supply     meter, 29; a mixer, 30, to mix this air and natural gas in     approximately stoichiometric proportion; a delivery pipe, 31, to     deliver this supplementary fuel air mixture into the supplementary     overfire burn zone, 40; and a spark igniter, 32, to ignite the     mixture.

I. DESCRIPTION OF ELEMENTS

-   17. The several compressor air supply meters, 12, 15, 20, 24, 27,     29, and fuel gas supply meters, 17, 33, are preferably positive     displacement meters, with variable speed drivers. Roots blowers,     such as described in Reference F, are an example of a suitable     positive displacement gas supply meter. Fully controllable air and     gas flow rates could be achieved, by use of such Roots blower gas     meters, driven by variable speed electric motors, with the air and     fuel gas supplied to the gas meter inlet, at a constant pressure,     essentially equal to gas turbine engine compressor discharge     pressure. The Roots blower meters would be doing very little     compressing, only enough to offset gas flow pressure loss through     the fuel beds. Reciprocating piston and cylinder displacers are     another type of positive displacement air meter or gas meter.     Variable speed drivers, such as compressed air motors, could     alternatively be used to drive the positive displacement gas and air     meters. A controllable speed Roots blower functions as a combined     flow rate controller and meter with flow rate being essentially     linear in the product of blower displacement per revolution and     shaft revolutions per unit time.

When using free burning, non caking, coals, at essentially steady coal burn rates, adjustable flow dampers could alternatively be used to distribute the compressor air flow portions, into the several burners, mixers and reactors. But where caking coals were being used, with consequent variations in coal bed flow resistance, or where coal burn rates varied over a wide range, such flow dampers would require frequent adjustment, and a meter, or other sensor means, to check on flow rates.

-   18. The refuel mechanism and driver, 3, functions to periodically     transfer a refuel quantity of coal, from an external source at     atmospheric pressure, into the bottom of the ODD reaction chamber,     2, and to positively force this refuel quantity into the reaction     chamber, thus concurrently causing transfer of a coke quantity, from     the upper, gas outlet end, 34, of the ODD reaction chamber, into the     upper end, 5, of the coke reactor 6. The refuel mechanism is to     carry out this transfer of coal, while keeping the ODD reaction     chamber sealed against leakage. The refuel mechanism driver is     controlled to thusly intermittently transfer coal, into the ODD     reaction chamber, and coke into the coke reaction chamber, in order     to maintain an adequate depth of the carbon dioxide burn zone, 25.     This controller of the refuel driver is described hereinbelow.     Various types of refuel mechanism, and drivers, and controllers, can     be used for these purposes in this invention.

An example of a suitable disc or plate type force feed refuel mechanism is described in U.S. Pat. No. 5,485,812, Firey, 23 Jan. 1996, in FIG. 2, and column 4, lines 16 through 45. For purposes of the present invention, a mask element can be added, between the refuel driver piston, 35, and the reaction chamber, 7, to prevent fuel bed slumping when the driver piston, 35, is retracted at the time of movement of the transfer plate, 33. Also the driver piston, 35, stroke length would be limited to the depth of the refuel cavity, 34. This material from U.S. Pat. No. 5,485,812 is incorporated herein by reference thereto.

Another example of a suitable rotary force feed refuel mechanism is described in U.S. Pat. No. 4,653,436, Firey, 31 Mar. 1987, and this material is also incorporated herein by reference thereto. This rotary force feed mechanism can also be adapted for use as an ash removal mechanism, for purposes of the present invention, as is described in U.S. Pat. No. 4,653,436.

The refuel mechanism driver controller, for the present invention, may differ from the driver controllers described in these referenced US patents.

Another example refuel mechanism is illustrated schematically in cross section in FIGS. 7, and 8, and comprises the following components:

At the lower refuel end, 4, of the ODD reaction chamber, 2, the refuel mechanism, 3, comprises:

-   -   (a) The refuel cavity, 47, in the refuel block, 48, can be         aligned with the ODD reaction chamber, 2, as shown, or can be         aligned with the refill hopper, 49, for refilling with coal         chunks, by the refuel block pneumatic driver, 50, acting to         thusly slide the refuel block back and forth;     -   (b) The refuel mask hole, 51, in the refuel mask, 52, can be         aligned with the ODD reaction chamber, 2, as shown, or can be         non aligned therewith in order to close off the refuel end, 4,         of the ODD reactor. The refuel mask is thusly driven back and         forth by a mask pneumatic driver similar to the refuel block         pneumatic driver;     -   (c) The refuel piston, 54, is shown fully retracted out of the         refuel cavity, 47, and can be driven fully into the refuel         cavity, 47, by the refuel piston pneumatic driver, 55, when both         the refuel cavity, 47, and the mask hole, 51, are aligned with         the ODD reactor, 2;     -   (d) In this way a refuel package of coal chunks can be         transferred, from the refuel hopper, 49, into the refuel end, 4,         of the ODD reaction chamber, 2, and retained therein by the         refuel mask while the refuel cavity, 47, is being refilled for         the next following refuel.     -   (e) A coke transfer ram, 56, can be used to force those coal         chunks, forced up out of the ODD reactor, 2, during refueling,         across into the exit end, 57, of the coke reaction chamber, 7,         following after each refueling. The coke transfer ram is thusly         driven across, and retracted, by a coke transfer ram pneumatic         driver not shown. A coke transfer ram will not be needed for         those designs, wherein the angle between the ODD reactor         centerline, and the coke reactor centerline, is large, as shown         in FIG. 1;     -   (f) The refuel block, the refuel mask, the refuel driver piston,         and the coke transfer ram are sealed against leakage and these         seals are not shown in these schematic figures;     -   (g) The several pneumatic drivers, 50, 53, 55, may differ in         required driver piston area, and stroke length, but are         functionally similar in components, and operation. Details of         the refuel block driver, 50, are presented herewith as typical         for all drivers:         -   (i) The driver piston, 59, operates sealably within the             driver cylinder, 60, and is connected to the refuel block,             48, via the piston rod, 61;         -   (ii) Each end of the driver cylinder, 60, can be alternately             pressurized or vented, via the values, 62, 63, connecting to             a pressure source, 64, or a vent, 65, in order to drive and             retract the piston, 59, and hence the refuel block, 48;         -   (iii) The pressure and vent values, 62, 63, can be solenoid             actuated, if an electrical or electronic refuel controller             is used. Other value actuators, such as hydraulic or             pneumatic could alternatively be used;     -   (h) The operating sequence of the refuel mechanism, at the end         of a refuel time interval is as follows:         -   (i) The mask hole, 51, is aligned to the ODD reactor, 2;         -   (ii) The refuel piston, 54, drives the refuel package of             coal into the ODD reactor, 2;         -   (iii) The coke transfer ram, 56, crosses the ODD reactor             exit, to the coke reactor exit, thus transferring coke fuel,             from the ODD reactor, 2, into the exit of the coke reactor,             7;         -   (iv) The coke transfer ram, 56, is fully retracted;         -   (v) The mask hole, 51, is non aligned to the ODD reactor, 2;         -   (vi) The refuel piston, 54, is retracted out of the refuel             cavity, 47;         -   (vii) The refuel block, 48, moves the refuel cavity, 47, out             of alignment to the ODD reactor, 2, and into alignment with             the refill hopper, 49;         -   (viii) after a refill delay interval, to allow refilling of             the refuel cavity, 47, with fresh coal chunks, the refuel             block, 48, moves the refuel cavity, 47, out of alignment to             the refill hopper, 49, and into alignment to the ODD             reactor, 2;     -   (i) An example electronic refuel control means, 66, for         controlling the several solenoid operated valves, 62, 63, on the         several drivers, 50, 55, 58, of the refuel mechanism, in order         to carry out the above refuel mechanism sequence, at the end of         each refuel time interval is shown schematically in FIG. 2. This         refuel controller, 66, receives several input signals, from         position sensors, on each moving element of the refuel         mechanism, 3, and sends output signals to the solenoid actuators         of the refuel mechanism valves, 62, 63. The refuel mechanism         sequence is initiated by an input to the refuel controller, 66,         from the coal controller, 37 as described hereinbelow;

-   19. The ash removal mechanism and driver, 8, functions to     periodically transfer a quantity of ashes from the coke lower ash     removal end of the reactor chamber, 7, at high pressure, into an     external ash receiver at atmospheric pressure. The ash removal     mechanism is to carry out this transfer of ashes, while keeping the     coke reactor chamber sealed against leakage. The ash removal     mechanism driver is controlled to thusly, intermittently, transfer     ashes, out of the coke reactor chamber, and into an external ash     receiver, only when sufficient ashes collect, at the bottom of the     coke reactor that a protective ash layer, 10, remains always     present, between the hot burning coke in the oxygen burn zone, 11,     and the ash removal mechanism, 8. This controller of the ash removal     mechanism driver is described hereinbelow. Various types of ash     removal mechanism, and drivers, and controllers, can be used for     these purposes in this invention.

An example of a suitable sliding plate type of ash removal mechanism is described in U.S. Pat. No. 5,613,626, Firey, 25 Mar. 1997, and this material is incorporated herein by reference thereto. The ash removal mechanism driver controller for the present invention may differ from the driver controller described in referenced U.S. Pat. No. 5,613,626. The mechanism, described in U.S. Pat. No. 5,613,626, can also be modified to function as a positive, force feed, refuel mechanism, as described therein on column 7, lines 6 through 44.

The ash removal form of the mechanism, described in U.S. Pat. No. 5,613,626, provides for positive removal of the ash from the ash cavity, 5, by the transfer driver piston, 6, and subsequently also by the dump driver piston, 25. Such positive final dumping of the ashes may be preferred when ash klinkering is a problem, as with those coals having a low ash fusion temperature.

-   20. Various types of drivers can be used for the driving of the     refuel mechanism, 3, and the ash removal mechanism, 8, such as     electromechanical drivers, wholly mechanical drivers, hydraulic     drivers, and pneumatic drivers. In some gas turbine applications     pneumatic drivers may be preferred, since high pressure air is     readily available from the compressor discharge. Linear or rotary     pneumatic drivers can be controlled by solenoid operated valves, or     by pneumatically operated valves, the solenoid valves being often     preferred when electronic engine governors are used.

The refuel mechanism, 3, when driven through a refuel cycle by the driver, delivers an essentially constant volume of coal into the ODD reaction chamber, 2, on each cycle. The average rate of coal supply into the ODD reaction chamber, can be controlled by adjusting the length of the refuel time interval, (tRF), between refuel cycles, coal supply rate increasing when refuel time interval is shortened. The refuel time interval can be thusly adjusted by the controller, in terms of clock time, or, for constant speed gas turbine engines, in terms of engine shaft revolutions between refuel cycles.

The ash removal mechanism, 8, when driven through an ash removal cycle by the driver, removes an essentially constant volume of ashes from the coke reaction chamber, 7, on each cycle. An example controller, of this ash removal process, senses the ash depth in the chamber 7, as by a thermocouple or infrared temperature sensor, and, when ashes accumulate to the sensor depth, and thus reduce the temperature there, initiates an ash removal cycle. The sensor depth is set high enough above the ash removal mechanism, that, after completion of an ash removal cycle, an adequate depth of ash remains to protect the ash removal mechanism from the very hot oxygen burn zone, 11.

-   21. Various types of oil or gas burners can be used for the ODD     reactor burner, 14, and the supplementary fuel air mixer, 30, and     overfire burner, 26, as are well known in the prior art of oil and     gas burners. Several example descriptions of such prior art oil and     gas burners are presented in references G, H, I & J;

The ODD reactor burner, 14, and ODD mixer, 19, can be combined, as is common practice with aircraft gas turbine engine burners and cooling air mixers.

In both the ODD reactor burner, 14, and the supplementary fuel air mixer, 30, the ratio of fuel to air is to remain constant, at somewhat fuel lean from stoichiometric, and the fuel supply meters, 17, 33, and corresponding air supply meters, 15, 29, are to function in this manner. For example, where natural gas fuel is used, with positive displacement air and gas supply meters, a common drive can be used to drive both the fuel meter, and the air meter, at the same speed, with the ratio of meter displacement volumes per revolution being equal to the intended fuel to air ratio.

-   22. Operating a gas turbine engine simultaneously on two separate     fuels, coal and natural gas, will require adjustments of the burn     rate of both fuels, when turbine load changes, in order to keep     turbine shaft speed within narrow limits. This multifuel governing     of turbine speed can be carried out in various ways, one particular     example of which is shown schematically in FIG. 2, in combination     with FIG. 1, and described as follows:

When gas turbine engine load increases, a sensor of turbine power output, such as an electric generator wattmeter, 36, or a turbine power output shaft torque meter, could act via a coal controller, 37, to carry out the following control functions:

-   -   (a) The flow rates of air; into the coke reaction chamber, 7,         via supply air meter, 12; into the carbon monoxide overfire         burner, 26, via air supply meter, 27; into ODD burner, 14, via         supply air meter, 15; into the ODD mixer, 19, via air supply         meter, 20; and into the ODD overfire burner, 23, via air supply         meter, 24; are all increased and the ratios between these air         flow quantities and also between these air flow quantities and         the fuel flow quantities, remain essentially constant, as long         as the same fuels are being burned. Also the flow rate of gas         fuel, or liquid fuel, into the ODD burner, 14, via fuel supply         meter, 17, is increased in proportion to the flow rate of air         thereinto.     -   (b) The coal burn rate will thus be increased, as needed to         increase gas turbine engine power output to equal the increased         load. But this response of coal burn rate will be somewhat         sluggish, due in part to the intermittency of refuel cycles, and         in part to the time required to heat up the freshly refueled         coal to an adequate reaction temperature. This sluggish response         of coal burn rate could cause undesirable variations in gas         turbine engine shaft speed.     -   (c) A turbine shaft speed sensor, 38, acts via a speed         controller, 39, to increase the flow of supplementary fuel air         mixture, from the mixer, 30, into the supplementary overfire         burner, 40, when shaft speed decreases due to increased load.         The resulting increase of energy release will be rapid, since         gas or liquid fuel is burned in the supplementary overfire         burner, 40, and thus turbine shaft speed can be governed within         narrow limits.     -   (d) A comparator, 41, compares the energy release of the coal         burner, via a sensor signal, 42, from the coal controller, 37,         to the energy release of the supplementary overfire fuel air         mixture, via a sensor signal, 43, from the speed controller, 39,         and acts via a comparator output, 44, on the coal controller,         37, to adjust the coal burner energy release, so as to maintain         the ratio of coal energy release, to supplementary fuel air         mixture energy release, within a narrow band, about a set value,         for the energy release rate ratio, ER.         $({ER}) = \frac{\left( {{Coal}\quad{energy}\quad{Release}\quad{Rate}} \right)}{\left( {{Supplementary}\quad{Fuel}\quad{Air}\quad{Mixture}\quad{Energy}\quad{Release}\quad{Rate}} \right)}$         -   This set value, for the energy release rate ratio, ER, could             be adjustable, as by hand, within the comparator, 37, in             order to accommodate to changes in relative fuel prices, or             availability.     -   (e) Hunting of this gas turbine engine governor system can be         minimized by the width of the narrow band of values, of energy         release rate ratio, within which the comparator, 41, acts on the         coal controller, 37, to adjust the coal burner burn rate.

-   23. Within the coke burner, 7, the carbon dioxide, formed in the     oxygen burn zone, 11, is preferably to be largely reacted with the     coke, in the carbon dioxide burn zone, 25, to form a coke burner     exit gas, rich in carbon monoxide, and low in carbon dioxide. This     carbon monoxide rich coke burner exit gas can readily form fully     burnable fuel air mixtures, when admixed with overfire air, in the     carbon monoxide overfire burn zone, 26. To achieve this preferred     result, an adequately deep carbon dioxide burn zone is preferred to     provide sufficient coke surface area for the carbon dioxide reaction     therewith. A coke fuel depth controller, responsive to a coke fuel     depth sensor, and operative upon the refuel mechanism driver, 3, can     function to maintain an adequately deep carbon dioxide burn zone,     25. Various types of such coke fuel depth controllers can be used. A     particular example controller is illustrated schematically in FIG. 3     and FIG. 2 and described as follows:     -   (a) Several separate optical depth sensors, 45, are placed along         a length of the coke reactor, 6, both above and below the         desired total coke fuel depth, ZT. These optical sensors send a         radiation beam, of shorter wavelength than emitted by the hot         burning coke, across the reactor to a receiver of this type of         radiation, on the opposite side of the reactor. The total fuel         bed depth will be sensed, as less than the lowest such sensor         for which the radiation reaches the receiver, and greater than         the highest such sensor for which the radiation fails to reach         the receiver, being blocked by the coke.     -   (b) A controller, 66, compares the total coke fuel depth, (Z),         thusly sensed, to the desired minimum coke fuel depth, (Zmin),         and initiates a refuel cycle, from the refuel mechanism, 3,         whenever sensed depth, (Z), is less than minimum desired coke         depth, (Zmin).     -   (c) The controller, 66, also compares the coke fuel depth, (Z),         thusly sensed, to the desired maximum coke fuel depth, (Zmax),         and suppresses the next refuel cycle, of the refuel mechanism,         3, when called for by the coal controller, 37, when sensed         depth, Z, exceeds maximum depth, Zmax.

-   24. Theoretically, the effective coke fuel bed depth, Z, could be     controlled by sensing the carbon monoxide and carbon dioxide, molal     fractions, in the coke fuel bed exit gas. The sum of these two molal     fractions, corrected for the change in mols of gas flowing through     the coke reactor, 7, equals the mols of carbon gasified within the     reactor per mol of primary air flowing into the reactor, via the     primary air meter, 12. As more of the carbon dioxide, formed in the     oxygen burn zone, 11, is reacted further with carbon, in a deeper     carbon dioxide burn zone, 25, to form increased carbon monoxide, the     mols of carbon gasified, per mol of primary air, is thus increased.

This coke bed exit gas composition sensor has the advantage that coke fuel bed depth is automatically compensated for changes in coke fuel chunk size (dCH), and primary air flow rate, (G₀). However, drawing a suitable sample of coke fuel bed exit gas, for this composition sensor to analyze, is a difficult problem.

Automatic sensor and control apparatus, as described hereinabove, will usually be preferred, but hand sensor and control methods could also be used, for example in small plants.

-   25. The coke fuel burner enclosure, 6, is preferably designed with a     useable fuel bed depth, between the ash removal mechanism, 8, and     the entry level of coke transfer from the ODD reactor 1 adequate for     the maximum intended primary air flow rate, (G₀), and the largest     coke fuel chunk size, (dCH), to be used. -   26. When a mixed fuel coal burner of this invention is to be shut     down, the coke fuel bed, in the coke burner, 7, is preferably fully     burned up while maintaining gas turbine operation on the     supplementary fuel air mixture, from the mixer, 30, the refuel     mechanism, 3, being rendered inoperative during shut down. During     the next following startup, the ODD burner, 14, and mixer, 19, are     operated, in order to heat up the coal within the ODD reactor, 2, to     at least its devolatilization temperature. The gas turbine is     operated, at startup, on the supplementary fuel air mixture from the     mixer, 30. When the coal in the ODD reaction, 2, is sufficiently     heated, the refuel mechanism, 3, commences operation, in order to     transfer thusly heated coke into the coke burner, 7. In this way the     coke reaction, with primary air, can start, as soon as coke and     primary air start entering the coke reactor, 7. -   27. Various types of containers can be used to enclose the ODD     reaction chamber, 2, and the coke burner chamber, 7. For example,     these containers could comprise the following elements:     -   (a) A high temperature ceramic layer, such as alumina of high         density and strength, could be used for an abrasion resistant         inner liner, next to the reacting coal and coke.     -   (b) An insulating ceramic layer, such as a low density alumina,         could surround the inner liner.     -   (c) A cooling air channel could surround the insulating ceramic         layer, through which compressor discharge air is passed.     -   (d) A steel or alloy container could enclose the air channels,         and retain the high pressure air and gases; this high pressure         metal container would be protected from the high temperatures         prevailing in the ODD reactor and the coke reactor by the         intervening ceramic layers, and the cooling air channel. -   28. The mixed fuel coal burner of this invention, shown     schematically in FIG. 1, comprises a single ODD reactor, 2,     supplying coke into a single coke burner, 7. But for a gas turbine     engine, more than one coke burner could be used, and each such coke     burner could be supplied by more than one ODD reactor. If two or     more ODD reactors are used, for each coke burner, these could be     distributed about the coke burners, so as to achieve a more nearly     uniform distribution of coke across the coke burner cross sectional     area. -   29. A wide variety of coal types can be efficiently and cleanly     burned in a mixed fuel coal burner of this invention. Free burning     coals will often be preferred, where available at low prices. Where     caking coals are to be used, a moderate taper of the ODD reactor     chamber, 2, could be used, with chamber cross-sectional area     increasing in the direction of coal motion. -   30. Natural gas fuel is well suited for use as the fuel for the ODD     burner, 14, and also for the supplementary fuel air mixer, 30.     Distillate liquid petroleum fuels could alternatively be used in one     or both of these burners. Other kinds of gas fuels could also be     used in these burners.

II. REACTORS SIZING

The gas turbine engine type, size, speed, and allowable turbine inlet temperature, will determine the proportion of compressor discharge air available as air flow to the coal burner, at rated gas turbine engine power output. Also determined are the burner operating pressure (PO), the burner air inlet temperature (TA3°R), and the engine thermal efficiency relative to the lower heating value (LHV), of the coal.

The coal properties needed are the coal lower heating value (LHV), the weight fraction volatile matter, (VM), the weight fraction fixed carbon (FC), the weight fraction oxygen, and the weight fraction ash (ASH), by proximate analysis, and the coal density.

The equivalent coal chunk size (dCH), can be preselected as a design variable, or can be measured approximately by a technique described hereinbelow.

For the approximate reactor sizing methods described herein, the rough approximation is made that all coals have an “equivalent” molecular weight of 12, as carbon. This approximation ignores the different burning stoichiometry of the hydrogen and sulfur portion of a coal. However, the resulting design errors are small, since coal hydrogen contents are small.

The coal energy rate per megawatt of gas turbine rated power output (MW), can be calculated: $\frac{\left( {{{Coal}\quad{Energy}},{{Btu}\text{/}{Hr}}} \right)}{{MW}\quad{Power}\quad{Output}} = \frac{(3413000)}{\left( {{Engine}\quad{Efficiency}} \right)}$

And the coal feed rate into the ODD reactor, 2, by the refuel mechanism, 3, can be calculated: $\frac{\left( {{{Coal}\quad{Burn}\quad{Rate}},{{lbs}\text{/}{Hr}}} \right)}{\left. {{MW}\quad{Power}\quad{Output}} \right)} = \frac{(3413000)}{({LHV})\left( {{Engine}\quad{{Eff}.}} \right)}$ $\frac{\left( {{{Lb}.\quad{Mols}}\quad{coal}\quad 12} \right)}{\left( {{MW}\quad{Hr}} \right)} = {(J) = \frac{(284417)}{({LHV})\left( {{Engine}\quad{{Eff}.}} \right)}}$

The fuel for the ODD Burner, 14, and the supplementary overfire burner, 31, is, in this example calculation, assumed to be natural gas, composed largely of methane (CH4), each mol of which requires at least a stoichiometric air flow of 9.52 mols.

A. ODD Reactor Sizing

The ODD burner, 14, and mixer, 19, are to supply a hot gas, containing some oxygen, into the ODD reactor, 2 in order to increase the temperature of the coal therein, from the coal refuel temperature, (To°R), up to the coal rapid devolatilization temperature (Tcx°R). An energy balance on this overall process yields the following approximate relation for the molal ratio of ODD burner methane to coal: $\frac{{Mols}\quad{ODD}\quad{Burner}\quad{CH}_{4}}{{Mol}\quad{Coal}\quad 12} = {\frac{\left\lbrack {\left( {{Tcx}^{\circ}R} \right) - \left( {{To}^{\circ}R} \right)} \right\rbrack(0.56)}{\left\lbrack {\left( {{Tmx}^{\circ}R} \right) - \left( {{Tcx}^{\circ}R} \right)} \right\rbrack\left\lbrack {10.52 + {4.76W}} \right\rbrack} = (H)}$ $\frac{{lb}\quad{mols}\quad{ODD}\quad{Burner}\quad{CH}_{4}\quad{per}\quad{{Hr}.}}{{MW}\quad{Power}\quad{Output}} = {\frac{{Mols}\quad{ODD}\quad{Burner}\quad{CH}_{4}}{{Mol}\quad{Coal}\quad 12}(J)}$ Wherein:

-   -   4.76 W=Molal ratio of mixer air, via air meter, 20, to burner         CH4, via gas meter, 17, a design variable;     -   (Tmx°R)=Temperature of hot gas leaving the mixer, 19, and         flowing into the ODD reactor 2; °R;         $\left( {{Tmx}^{\circ}R} \right) = {\left( {{TA}\quad 3^{\circ}R} \right) + \frac{(344644)}{\left( {10.52 + {4.76W}} \right)(8.54)}}$

This relation between mixer exit gas temperature, (Tmx°R) and molal ratio of mixer air to ODD burner CH4, is shown graphically on FIG. 6, together with the variation of ODD mixer exit gas oxygen concentration.

-   -   (TA3°R)=Gas turbine engine compressor air discharge temperature,         OR;     -   (Tcx°R)=Temperature at which coal undergoes rapid         devolatilization.

The experimental data on rate of coal devolatilization, as a function of coal temperature, and heating gas temperature, presented in reference C, indicate that coal devolatilization is rapid at temperatures at or above 1500°R, and is essentially complete, for very small coal particles, in less than one minute's time. For larger coal chunks, the heat transfer process, from the hot through flow gas, into the coal chunks, is unsteady, the chunk centers being the last to reach a rapid devolatilization temperature, and hence the last to undergo devolatilization. Additionally, for coal chunks, the rate of heat transfer from the hot gas, into the coal, increases as throughflow gas mass velocity (Gf), increases due to thinning of the stagnant gas film on the coal surface. An approximate analysis of this unsteady heat transfer process, using the methods of Gurney and Lurie, as presented in reference D, together with the film heat transfer coefficient relations, for gas to a bed of solid chunks, presented in reference E, indicates that the coal chunk centers reach within 100 degrees Rankine of the adjacent hot gas temperature, in less than about two minutes' time, for hot gas throughflow mass velocities (G_(f)), above about 350 lbsmass, per hour, per square foot, of ODD reactor cross sectional area.

As described hereinbelow, the coal refuel process is intermittent, a refuel time interval, (tRF) intervening between refuel steps. Hence each refuel package of coal chunks remains inside the ODD reactor for at least one refuel time interval Since refuel time intervals will preferably exceed two minutes, it follows that essentially complete devolatilization of the coal fuel chunks can occur in the ODD reactor during the first refuel time interval.

Devolatilization of the central portions of a coal chunk may take place in the absence of the oxygen needed for partial oxidation to prevent tar and soot formation. Hence the amount of tar and soot may increase as coal chunk size is increased.

The molal air flow rate to the ODD burner, via air supply meter, 15, can be estimated as about 9.52 times the molal CH4 flow rate into the burner, via gas supply meter, 17.

Volatile matter, emerging from the coal chunks in the ODD reactor, 2, during devolatilization, mixes into the hot oxygen containing gases from the mixer, 19, flowing through the ODD reactor. Thus the emerging volatile matter has first call on the oxygen available in these throughflowing gases. To avoid any oxidation of the coke, formed by devolatilization, to ashes while within the ODD reactor, the oxygen available for the coal volatile matter is preferably less than the stoichiometric oxygen, for full burnup of the volatile matter. In this way, only partial oxidation of the volatile matter takes place, and essentially all of the oxygen, in the throughflowing gases, is reacted only with emerging volatile matter. Ash formation is to be avoided, within the ODD reactor since the small ash particles, emerging at the ODD reactor upper gas exit, can easily be carried into the turbine blades by the throughflowing gas. This preferred operation, of the ODD reactor can be achieved by controlling the flow of mixer air, into the ODD mixer, 19, to be less than stoichiometric for the flow of coal volatile matter, into the ODD reactor by refueling.

An approximate energy balance on the ODD reaction chamber, 2, yields the following relations for the coal temperature (Tcx°R), in the chamber: $\frac{\left\lbrack {{(L)\left( {{Tmx}^{\circ}R} \right)} + \left( {{To}^{\circ}R} \right)} \right\rbrack}{\left\lbrack {1 + L} \right\rbrack} = \left( {{Tcx}^{\circ}R} \right)$ $\frac{\left( {10.52 + {4.76W}} \right)(8.54)}{\frac{\left( {{Mols}\quad{Coal}\quad 12} \right)}{\left( {{Mol}\quad{ODD}\quad{Burner}\quad{CH}_{4}} \right)}(4.80)} = (L)$ $\frac{{Mols}\quad{Coal}\quad 12}{{Mol}\quad{ODD}\quad{Burner}\quad{CH}_{4}} = {\frac{{lbs}\quad{mass}\quad{Coal}\quad 12}{(12)\left( {{Mol}\quad{Burner}\quad{CH}_{4}} \right)} = \left( \frac{1}{H} \right)}$

For this ODD reaction chamber energy balance, the approximation is made, that the endothermic heat of reaction of the destructive distillation of the volatile matter, is offset by the exothermic heat of reaction of the partial oxidation of the volatile matter.

The fraction of stoichiometric oxygen flowing through the ODD reactor relative to the flow rate of coal volatile matter can be estimated by the following relations: $\begin{matrix} {{(r) = {{Fraction}\quad{of}\quad{stoichiometric}\quad{molecular}}}\quad} \\ {{{oxygen}\quad{relative}\quad{to}\quad{coal}\quad{volatile}\quad{matter}};} \end{matrix}$ $(r) = \frac{(w)(H)}{({VM})}$ Wherein:

-   -   VM)=Weight fraction volatile matter content of coal as         devolatilized; can be estimated for sizing purposes from the         coal proximate analysis.

An example ODD reactor chamber energy balance result is shown graphically on FIG. 4, for a coal with a volatile matter weight fraction of 0.35, and for a range of values of coal devolatilized temperatures, (Tcx°R), and also a range of value of (r), the stoichiometric oxygen fraction.

On this coal, the ODD reaction chamber could be operated at the following example conditions, as shown on FIG. 4:

-   -   (Tcx°R)=Coal Rapid devolatilization temperature=1660°R(1200° F.)     -   (r)=Stoichiometric oxygen fraction= 0.40         ${\frac{{Mols}\quad{Coal}\quad 12}{{Mol}\quad{ODD}\quad{Burner}\quad{CH}_{4}}36};{\frac{{Mols}\quad{Coals}\quad 12}{{MW}\quad{{Hr}.}} = {36(H)(J)}}$         ${\frac{{Mols}\quad{ODD}\quad{Mixer}\quad{Air}}{{Mol}\quad{ODD}\quad{Burner}\quad{CH}_{4}} = 24};{\frac{{Mols}\quad{ODD}\quad{Mixer}\quad{Air}}{{MW}\quad{{Hr}.}} = {24(H)(J)}}$         $\frac{{Mols}\quad{ODD}\quad{Mixer}\quad{Air}}{{Mol}\quad{Coal}\quad 12} = 0.667$

Preferably, the ODD reaction chamber is to be operated, with the stoichiometric oxygen traction less than 1.0, to assure no ash formation within the ODD reactor, as described hereinabove.

At very low values of (r), the desired partial oxidation of the volatile matter may be incomplete, resulting in increased formation of soot and tar. For values of (r) close to stoichiometric, burnup of the volatile matter may be almost completed within the ODD reactor. The subsequent overfire burning, of the small residual unburned volatile matter, may be incomplete, due to excess dilution of the reactants. Hence intermediate values of (r) are preferable, to be selected experimentally, at full overfire burnup of coal volatile matter, with minimum soot and tar.

Whatever soot and tar are formed in the ODD reactor can be largely removed from the gases flowing through the reactor, by filtering these gases through a deep bed of the coke chunks, produced by the devolatilization process. For this reason, each refuel package of coal chunks preferably remains inside the ODD reactor for several refuel time intervals. The depth of the coal bed, inside the ODD reactor preferably sufficient to hold at least two refuel packages, and preferably more. With three or more refuel packages, within the ODD reactor the most recent package can function to insulate the refuel mechanism, by admitting the hot oxygen containing gas well above the refuel mechanism, as shown in FIG. 9.

The longer the residence time inside the ODD reactor the greater the extent of capture of soot and tar, and the more completely these captured products of devolatization are transformed into coke, and subsequently transferred into the coke reaction for complete burnup to CO₂.

For preferred filtering of soot and tar, within the ODD reactor the depth of the ODD reactor (LODDR), is to be essentially a constant, and independent of the refuel package volume, (RCV), or the refuel time interval (tRF). This depth is another design variable, wherein greater depth yields more complete capture of soot and tar, together with a larger pressure drop through the ODD reactor.

The volume of a cylindrical ODD reactor, (VODDR), can be estimated as follows:

Wherein:

-   -   (AODDR)=ODD reactor cross sectional area, in square feet;     -   (LODDR)=ODD reactor length up to where the coke is spilled over         into the coke reactor, in feet.         Also:     -   (VODDR)=(RCV)(NRP)     -   (RCV)=Refuel package volume, ft³     -   (NRP)=Number of refuel packages within the ODD reactor;

The ODD reactor cross sectional area, (AODDR) can be estimated in terms of the throughflow gas mass velocity (G_(f)), which is a design variable. (Gf)(AODDR)=(292+138w)(H)(J)(MW Power Output) Wherein:

(Gf)=pounds mass flow, per hour, per square foot of ODD reactor cross section area, when empty, of gases flowing through the ODD reactor excluding the volatile matter flow;

Design values of the throughflow gas mass velocity (Gf), and hence of the ODD reactor class sectional area (AODDR), can be based on the following considerations:

-   -   (a) The gas mass velocity must be well below the chunk lift off         velocity, as described hereinbelow, for the coke reactor     -   (b) At higher gas mass velocity, heat will transfer more quickly         into the coal chunks, and the resulting more rapid         devolatization may reduce soot and tar yields, by reducing the         residence time of the volatile matter within the interior pores         of the coal chunks; but pressure drop through the ODD reactor         coal bed will increase, and reduced gas turbine engine         efficiency, will result;     -   (c) At reduced gas mass velocity, a larger ODD reactor cross         sectional area is needed, which invites uneven devolatization,         due to uneven gas flow distribution over the cross sectional         area. But pressure drop through the ODD reactor coal bed will         decrease and gas turbine engine efficiency loss will be reduced;

Tentatively, design values for gas mass velocity (Gf), appear to lie preferably between about 300 lbsmass, per square foot, per hour, and about 1500 lbsmass, per square foot, per hour;

Design values for the refuel package volume (RCV), as well as the refuel time interval (tRF), are more readily determined from the coke reaction sizing, as described hereinbelow.

B. Coke Reactor Sizing

As primary air flows through the reacting coke fuel bed, the oxygen reacts rapidly with the carbon fuel, by diffusing through a stagnant gas film, to the hot carbon surface. This reaction is rapid, and oxygen is largely depleted within the early portions of the fuel bed, the reaction products being mostly carbon dioxide, with some carbon monoxide. The carbon dioxide subsequently reacts further with the carbon surface, by diffusing back thereto, and forms additional carbon monoxide further along in the fuel bed. The carbon dioxide reaction, with the carbon surface, is appreciably slower than the oxygen reaction therewith. Nevertheless, the early formed carbon dioxide is, in turn, depleted as the gases flow further through the fuel bed. The gases, leaving the fuel bed, may thus contain carbon monoxide, and some carbon dioxide, plus nitrogen, with only trace amounts of surviving oxygen.

In an equilibrium coke fuel bed, all of the fuel, supplied to the top of the coke reactor, from the exit of the ODD reactor is gasified, and only ashes remain at the bottom of the coke reactor. Thus coke feed rate, into the coke reactor is to equal carbon gasification rate therein. This carbon gasification rate is proportional to the rate at which oxygen is supplied into the coke reactor by the primary air, supplied via the positive displacement air supply meter, 12. As primary air flow rate, G₀, is increased, the stagnant gas film on the carbon surface becomes thinner, and both oxygen and carbon dioxide react more rapidly with the carbon.

Two differing reaction zones are thus created within the reacting coke fuel bed: an oxygen burn zone, 11, where oxygen in the primary air reacts rapidly with carbon, to form largely carbon dioxide, with some carbon monoxide; and a carbon dioxide reaction zone, 25, where the carbon dioxide, from the oxygen burn zone, reacts further with carbon, to form additional carbon monoxide. These two reaction zones overlap in part. The carbon dioxide reaction, while slower than the rapid oxygen reaction, is nevertheless rather fast, the endothermic heat of the carbon dioxide reaction being supplied by heat transfer to the coal chunks from the very hot gases, flowing out of the oxygen burn zone.

For efficient combustion, all of the carbon monoxide, formed inside the coke reactor, 7, is to be burned further to carbon dioxide, in an overfire burner, 26, supplied with overfire air via the air supply meter, 27.

As the coke reactor exit gas carbon monoxide concentration is decreased, a weaker carbon monoxide plus air overfire flame results. With room temperature reactants, a carbon monoxide in air flame becomes non-burnable at molal diluent ratios (DRCO), greater than about 0.55, as described in reference B. This dimensionless molal diluent ratio can be described as follows: $({DRCO}) = \frac{\left( {{Diluent}\quad{gases}} \right)}{\left( {{Diluent}\quad{gaes}} \right) + \left( {{Air}\quad{For}\quad{CO}\quad{Burnup}} \right)}$

The nitrogen and carbon dioxide, in the coke reactor exit gases, are the principal diluents, and the carbon monoxide overfire air, supplied via air supply meter, 27, is the air for CO burnup. At elevated gas temperature, the carbon monoxide flame, being less chilled, becomes burnable at diluent ratios greater than 0.55, but the relation of usable diluent ratio to gas temperature is not well established.

Herein, the conservative sizing assumption is illustrated, that a molal diluent ratio no greater than about 0.55 is used, for the carbon monoxide overfire burner, 26, and that the coke fuel bed, in the coke reactor, is to be sufficiently deep to react most of the diluent carbon dioxide into carbon monoxide, in order to achieve this diluent ratio.

Some bituminous coals break up, during devolatization, into smaller coal chunks. As a result the coal chunk equivalent diameter (dCHE), within the coke reactor, may be one half, or one fourth, or less, of the coal chunk diameter (dCH), as refueled into the ODD reactor. These smaller coal chunks offer a greater surface area for the oxygen and carbon dioxide reactions, which thus occur more rapidly, and a shallower coke fuel bed will be adequate to meet the diluent ratio requirement.

Herein, the additional conservative sizing assumption is illustrated, that the coke chunk diameter (dCHE) is the same as the coal chunk diameter (dCH), for sizing the coke fuel bed depth, within coke reactor. The resulting design coke fuel bed depth will be adequate for coals which do not break up on devolatization, and will be more than adequate for those coals which break up into smaller chunks.

The relations of, fuel bed exit gas composition, mols carbon gasified per mol of primary air, and diluent ratio of the coke fuel bed exit gas at overfire, obtained by approximate analysis of this model of the fuel bed reactions, are plotted graphically in FIG. 5, against fuel bed depth factor (bm)(z); Wherein: $\left( \frac{p\quad\theta\quad z}{po} \right) = {{0.21\left\lbrack {\mathbb{e}}^{- {az}} \right\rbrack} = {{{Mol}\quad{Fraction}\quad{Molecular}\quad\theta\quad{z\left( \frac{pcoz}{po} \right)}} = {{{0.21\left\lbrack \frac{a}{a - {bm}} \right\rbrack}\left\lbrack {{\mathbb{e}}^{- {bmz}} - {\mathbb{e}}^{- {az}}} \right\rbrack} = {{Mol}\quad{Fraction}\quad C\quad\theta\quad z}}}}$

-   -   (PO)=Compressor discharge pressure;         ${(z) = {{{Dimensionless}\quad{fuel}\quad{bed}\quad{depth}} = \frac{Z}{dCHE}}}\quad$     -   (dCHE)=Fuel chunk equivalent diameter in the coke reactor;     -   (Z)=Fuel bed depth in same dimensions as the fuel chunk         diameter;     -   (a)=Dimensionless diffusion and reaction factor for oxygen         reaction with carbon surface;     -   (bm)=Dimensionless diffusion and reaction factor for the carbon         dioxide reaction with carbon surface         $(a) \cong \frac{3.375}{({ReO})^{0.3}}$ (bm) ≅ (0.315)(a)         $\begin{matrix}         {({ReO}) \cong {(9.46)\left( G_{0} \right)({dCHE})}} \\         {= {{Coke}\quad{Reynolds}\quad{Number}{\quad\quad}\underset{\_}{Reaction}\quad\underset{\_}{Chamber}{\quad\quad}{Grate}}}         \end{matrix}$     -   (G₀)=Primary air mass velocity through coke reactor grate, when         empty, lbsmass air, per hour, per square foot grate area;         $\frac{{Mols}\quad{Carbon}\quad{Gasified}}{{Mol}\quad{Primary}\quad{Air}} \cong \left\lbrack {\left( \frac{pcoz}{po} \right) + \left( \frac{pcO}{po} \right)} \right\rbrack$

These analytical results, shown in FIG. 5, agree reasonably well with experimental results, such as are presented in reference A, even though the mol fractions were not corrected for the changes in total number of mols, due to reaction.

The preferred operating range, for the coke reactor, shown in FIG. 5, lies between a fuel bed depth factor (bm)(z), of about 1.6, at the diluent ratio limit for carbon monoxide burnability at overfire, and a fuel bed depth factor about 3 to 4, at the carbon dioxide depletion limit, hence:

1.6<(bm)(z)<4.0 Within this preferred coke reactor operating range, the carbon gasification rate is roughly constant, at about 0.40, as shown in FIG. 5: $0.35 < \frac{{Mols}\quad{Carbon}\quad{{Gasif}.}}{{Mol}\quad{Primary}\quad{Air}} < 0.42$

The reacting fuel bed depth (Z), in feet, can be calculated in terms of the fuel bed depth factor (bm)(z):

The total coke fuel bed depth, (ZT), is to exceed these reacting bed depths, by an additional ash bed depth, (ABD4), as described hereinbelow.

The maximum refuel quantity volume, (RCV) should be less than the product of coke reactor grate area, (GAR), times the maximum change of reacting fuel bed depth: (RCV)<[(Zmax)−(Zmin)](GAR), in ft.³

The required total coke reactor grate area, (GAR) is related to the primary air mass velocity (G₀), the carbon gasification rate, and the gas turbine power output (MW), as follows: ${\frac{({GAR})}{{MW}\quad{Power}\quad{Output}} = \frac{(284417)(29)({FCC})}{({LHV})\left( {{Engine}\quad{{Eff}.}} \right)({Go})(0.40)}};\frac{{ft}^{3}}{MW}$ Wherein: (GAR) = Total  coke  reactor  grate  area, Ft.²; $\begin{matrix} {{({FCC}) = {{Fractional}\quad{fixed}\quad{carbon}\quad{content}\quad{of}\quad{the}\quad{coal}\quad{as}\quad{reacted}}};} \\ {\underset{\_}{{{approximately}\quad{equal}\quad{to}\quad{proximate}\quad{analysis}\quad{fixed}\quad{carbon}};}} \end{matrix}$ $\begin{matrix} {{\left( G_{0} \right) = {{Primary}\quad{air}\quad{mass}\quad{velocity}\quad{through}\quad{empty}\quad{grate}}},} \\ {{{lbsmass}\quad{per}\quad{square}\quad{{ft}.\quad{per}}\quad{hr}};} \end{matrix}$ $\frac{{Mols}\quad{Carbon}\quad{Gasified}}{{Mol}\quad{Primary}\quad{Air}} \cong 0.40$

The refuel quantity (RCV), and refuel time interval (tRF), are related to the gas turbine engine power output as follows: $\frac{({RCV})}{({tRF})} = \frac{(284417)\left( {{MW}\quad{Power}} \right)}{({LHV})\left( {{Engine}\quad{Eff}} \right)({df})(5)({PF})}$ Wherein:

(RCV)=Volume of total refuel quantity in cubic feet;

(tRF)=Refuel time interval between refuel processes, mins.;

(df)=Coal fuel density, lbsmass per cubic foot;

For reactor sizing purposes, the refuel quantity, and refuel time interval, are selected for maximum gas turbine engine power output. At reduced power output, longer refuel time intervals are used, with a constant refuel quantity.

The internal volume of the coke reactor, 7, is to at least equal the product of grate area (GAR), and the total maximum coke fuel bed depth, (ZTmax)=[(Zmax)+ABD4)];

The net ash removal rate is necessarily related to the coal refuel rate, and the coal ash content, as follows: ${\frac{({RCV})}{({tRF})}({df})({PF})\left( {{Coal}\quad{{wt}.\quad{Fraction}}\quad{Ash}} \right)} = {\frac{({ARV})}{({tAR})}({da})({PF})}$ Hence: $\frac{({ARV})}{({RCV})} = {\frac{({df})}{({da})}\frac{({tAR})}{({tRF})}\left( {{Coal}\quad{{wt}.\quad{Fraction}}\quad{Ash}} \right)}$ Wherein:

(ARV)=Ash removal cavity, 8, volume;

(da)=Ash density;

(tAR)=Ash removal time interval;

The packing factor, (PF), is assumed equal for both coal particles and ash particles;

For the common case, where the ash removal cavity, 8, is fully aligned with the burner, the cross sectional area of the cavity, will equal the cross sectional area of the grate, (GAR).

To protect the ash removal mechanism, from the high temperature of the oxygen burn zone, 11, in the fuel bed, the minimum ash bed depth, (ABD3), is to exceed the ash removal cavity depth, $\frac{ARV}{GAR},$ by a protective ash bed layer, 10, of thickness, (PABD). Current experience with coal stokers indicates that a protective ash bed layer of as little as one or two inches is adequate.

During each ash removal interval, ash accumulates above the minimum ash bed depth (ABD3), up to the maximum ash bed depth (ABD4), at which depth the ash bed depth sensor initiates an ash removal process, which returns the ash bed depth to its minimum value (ABD3), by removing an ash volume of (ARV). Hence: $\left( {{ABD}\quad 4} \right) = {\left( {{Maximum}\quad{Ash}\quad{Bed}\quad{Depth}} \right) = {{(2)\left( \frac{ARV}{GAR} \right)} + ({PABD})}}$

The primary air mass velocity, (G₀), through the coke reactor grate area, is limited to less than the lift off mass velocity (GLO), at which coke chunks start to lift off the fuel bed. Design limiting values for (GLO) can be estimated from the following approximately relation: (GLO)=√{square root over ((dfx)(PF)(dCHE)(3.2×10⁶))} Wherein:

(GLO)=Air mass velocity, in lbsmass, per hour, per square foot of grate area, at incipient lift off;

(dfx)=Coke chunk density at fuel bed gas exit, in lbsmass per cubic foot;

(PF)=Coke chunk packing factor=0.74;

(dCHE)=Coke chunk equivalent diameter, in feet, at fuel bed gas exit;

The coke density at fuel bed gas exit (dfx), can be estimated as the coal density, reduced by the volatile matter removed in the ODD reactor; (dfx)=(df)(1−VMP)

(VMP)=coal volatile matter weight fraction; The coal chunk equivalent diameter, (dCHE), can be estimated as the coal chunk equivalent diameter, (dCH), divided by the number of fragments, (FRAG), into which the coal chunk breaks up during devolatilized: $({dCHE}) = \frac{({dCH})}{({FRAG})}$

An example calculation, of limiting air mass velocity (GLO), for a typical bituminous coal, is shown on FIG. 10 for several values of fragmentation factor (FRAG), and coal chunk starting size (dCH). For this particular coal, design values of coal chunk size of one inch or greater, can be selected, with air mass velocities up to about 1000 lbsmass per hour per square foot of grate area, or more.

Where several separate coke reactors are used, on a single gas turbine engine, and each of these separate coke reactors receive coke from several separate ODD reactors the total refuel quantities, and air and gas flow quantities, will usually be equally divided among these several reactors. Multiple coke reactors could have separate multiple overfire burners, or, alternatively, a single combined overfire burner could receive exit gases, from these several coke reactors, and all of their connected ODD reactors.

C. Overfire Burners Sizing

A mixed fuel coal burner of this invention, will use at least two overfire burners. In the ODD overfire burner, the partially oxidized volatile matter, emerging from the ODD reactor exit, is mixed with ODD overfire air, and ignited and burned, largely to CO2 and H₂O. In the carbon monoxide overfire burner the coke reactor exit gases, containing carbon monoxide are mixed with carbon monoxide overfire air and ignited and burned largely to CO₂ and H₂O. In this way the coal supplied to the reactors, is finally completely bummed, as desired for high engine efficiency, and these burned gases flow into the turbine inlet nozzles.

In many applications of mixed fuel coal burners, an additional supplementary overfire burner may be preferred, in order to assure close speed and load governing of the gas turbine engine. In this supplementary overfire burner, a supplementary fuel, such as natural gas, or distillate petroleum fuel, is mixed with supplementary overfire air, and ignited and burned in the supplementary overfire burner.

1. ODD Overfire Burner Sizings

-   -   ODD overfire air flow rate via air meter, 24, per megawatt of         gas turbine engine power output, can be estimated as follows,         for stoichiometric volatile matter burnup:         $\frac{\left( {{Lbmols}\quad{ODD}\quad{Overfire}\quad{{Air}/{Hr}}} \right)}{\left( {{MW}\quad{Power}\quad{Output}} \right)} = {(H)(J)(K)}$

Wherein:

-   -   (K)=(4.76)[(VMC12)−(w)−(Coal O₂)]         $\left( {{VMC}\quad 12} \right) = \left( \frac{VMP}{H} \right)$     -   (VMP)=coal volatile matter weight fraction, as reacted in the         ODD reactor.         -   (VMP) can be approximated as coal volatile matter weight             fraction, from proximate analysis;             $\frac{\left( {{Coal}\quad O_{2}} \right) = {\left( {{coal}\quad{{wt}.\quad{Fraction}}\quad O_{2}} \right)(12)}}{(32)(H)}$

2. Carbon Monoxide Overfire Burner Sizing

-   -   Where the coke reactor, 7, is operated within the preferred         range, with (bm)(z), greater than 1.6, and less than about 4.0,         the stoichiometric carbon monoxide overfire air, supplied via         the air supply meter, 27, can be estimated as follows:         $\frac{\left( {{{Lb}.\quad{Mols}}\quad{Overfire}\quad{Air}\quad{For}\quad{CO}\quad{Burnup}} \right)}{\left( {{MW}\quad{Hr}} \right)} = {(2.38)({FCP})(J)}$

Wherein:

-   -   (FCP)=coal fixed carbon weight fraction as reacted,         approximately equal to weight fraction fixed carbon by proximate         analysis;

3. Supplementary Overfire Burner Sizing

-   -   For many applications of mixed fuel coal burners, the         supplementary overfire burner is preferably sized to supply all         of the energy required by the gas turbine engine, and can be         adjusted over the full range, to supplying none of this energy.         In this way either coal or natural gas can be the principal         energy supplier for the engine.         $\frac{\left( {{{Lb}.\quad{Mols}}\quad{supplementary}\quad{Overfire}\quad{CH}\quad 4} \right)}{\left( {{MW}\quad{Hr}} \right)} \cong \frac{(9.903)}{\left( {{Engine}\quad{Eff}} \right)}$     -   Each mol of supplementary overfire CH4, supplied via gas meter,         33, will need a stoichiometric flow of 9.52 mols of         supplementary overfire air, supplied via air meter, 29.         D. Example Sizing Calculation

The following calculated results were obtained for a 25 MW gas turbine engine:

-   -   1. Gas turbine; 23 to 1 pressure ratio, 0.50 engine efficiency;     -   2. Bituminous coal; LHV−12350 Btu per lbsmass, 0.35 volatile         matter, 0.55 fixed carbon, coal devolatilization temperature,         1200° F., coal chunk diam.=1.25 ins.;     -   3. Selected operating conditions; Rated load, (r)=0.4 fraction         of stoichiometric oxygen in ODD reactor;     -   4. Calculated operating conditions:         -   (a) lbsmass coal per hour=13825 lbs/Hr.         -   (b) ODD burner methane−511 lbsmass/Hr.         -   (c) ODD burner air−8816 lbsmass/Hr.         -   (d) ODD mixer air=22230 lbsmass/Hr.         -   (e) Coke reactor, max. coke bed depth−3.1 ft.             -   Min. Coke bed depth−1.23 ft.         -   (f) Primary air=45920 lbsmass/Hr.         -   (g) ODD overfire burner air=33459 lbsmass/Hr.         -   (h) CO overfire burner air=43750 lbsmass/Hr.     -   5. Reactor dimensions:         -   (a) ODD reactor cross section area=31.5 sq.ft. At Gf=1000             lbsmass, per Hr., per sq.ft.;         -   (b) Coke reactor cross section area=45.9 sq.ft. At G₀=1000             lbsmass per Hr., per sq.ft.;     -   6. For a supplementary overfire burner capable of supplying the         entire energy requirements:         -   (a) Supplementary Overfire CH4=7924 lbsmass/hr         -   (b) Supplementary Overfire Air=136700 lbsmass/Hr.             E. Measurement of Coal Reaction Properties

Analysis of coke reactor exit gas composition, at one or more values of coke fuel bed depth, with overfire air briefly stopped, could provide experimental values for the reaction rate factors, (a), and (bm). With these data, obtained over a range of values of primary air flow rate, G₀, the coke bed reaction properties could be experimentally determined.

Coal chunk equivalent diameter, (dCH), can be approximated, if screened, as the average of the screen sizes. For unscreened, coal, or where chunk size varies widely, a light oil holdup versus time test, can be used to compare a coal against spherical chunks of known diameter.

III. INDUSTRIAL USES FOR THE INVENTION

A strong economic incentive exists to use low cost coal, in place of high cost natural gas, in gas turbine engine driven electric generators, As of October 2004, coal cost, per unit of energy, is about one fifth of the natural gas cost per unit of energy.

The mixed fuel coal burner, of this invention, describes apparatus, and a process, for clean burning of coal, in gas turbine engines, without ash particle carryover into the turbine blades.

At current fuel prices, as of October 2004, a fuel cost savings of about three cents per kilowatt hour can be realized by substituting coal for natural gas, in a gas turbine electric generator, such as a combined cycle plant.

A modified mixed fuel coal reactor of this invention could be used in cupola furnaces for melting cast iron or iron blast furnaces. The mixed fuel coal reactor creates two different fuel products from the coal, a clean burning fuel, derived from the coal volatile matter, and a coke fuel, derived from the coal fixed carbon. The coke fuel would be used in the cupola furnace, and the volatile matter derived fuel could be used as the energy source for a gas turbine, or piston engine, driving the air blower for the cupola furnace.

By adding limestone into the original coal, the sulfur oxides, formed from the coal sulfur content, and the nitrogen oxides, formed from the coal nitrogen content, can be captured, in the deep coke fuel bed of the coke reactor. In this way undesirable emissions of sulfur and nitrogen oxides can be reduced.

A gas turbine engine, using a mixed fuel coal burner of this invention, could be the electric power generator for a total energy system, to heat homes and factories cleanly, with low cost coal, instead of the high cost natural gas, or petroleum distillate, fuels currently used.

IV. REFERENCES

-   A. The Principles of Underfeed Combustion and the Effect of     Preheated Air on Overfeed and Underfeed Fuel Beds,” P. Nichols     and M. G. Eilers, Trans. ASME, Vol. 56, 1934, Paper FSP-56-5. -   B. “Combustion, Flames and Explosions of Gases,” B. Lewis and G. von     Elbe, p. 696-697, second edition, 1961, Academic Press, New York. -   C. “Coal Combustion and Gasification,” L. D. Smoot and P. J. Smith,     1985, Plenum Press, New York, p. 57-67. -   D. “Heat Transmission,” W. H. McAdams, first edition, 1933,     McGraw-Hill, New York; p. 30-39. -   E. “Heat, Mass, and Momentum Transfer,” W. Rohsenow, p. 202; -   F. “Mechanical Engineers Handbook,” L. S. Marks, fifth edition,     1951, McGraw-Hill, New York, p 1869-1871. -   G. “Thermal Engineering,” Solberg, Cromer, and Spalding, 1960, Chap     6, p 312-316, John Wiley, New York. -   H. “Steam,” Babcock and Wilcox Co., 38^(th) edition, 1972, Chap. 7,     p 7-2 through 7-10. -   I. “Aircraft Gas Turbines,” Smith, 1956, Chap. 13, John Wiley, New     York. -   J. “Theory and Design of Steam and Gas Turbines,” Lee, Chap. 14, p     428-432, McGraw-Hill, New York. -   U.S. Pat. No. 5,485,812; Firey, 23 Jan. 1996 -   U.S. Pat. No. 4,653,436; Firey, 31 Mar. 1987 -   U.S. Pat. No. 5,613,626; Firey, 25 Mar. 1997 

1. A mixed fuel coal burner, for the clean and controllable burning of coals containing volatile matter, and without ash being carried over with the burned gases leaving the burner, and comprising: a source of coal chunks containing volatile matter, and at atmospheric pressure; a source of compressed air at a pressure greater than atmospheric; an ash receiver at atmospheric pressure; a receiver of hot burned gases; and ODD reactor chamber and enclosure, and comprising a lower refuel end, a gas inlet near said refuel end, and an upper gas and coke outlet end; a coke reaction chamber and enclosure, and comprising a lower ash removal end, a gas inlet near said ash removal end, and an upper gas outlet end; said gas and coke outlet end of said ODD reactor chamber connecting into said gas outlet end of said coke reaction chamber; an overfire burner enclosure comprising at least two overfire burner chambers: an ODD overfire burner chamber, connected to said upper gas and coke outlet end of said ODD reactor chamber; and a carbon monoxide overfire burner connected to said upper gas outlet end of said coke reaction chamber; and further comprising igniter means for igniting fuel in air mixtures within said overfire burner chambers; and further comprising a gas outlet into said receiver of hot burned gases; a refuel mechanism for sealably transferring a refuel quantity of coal chunks, from said source of coal chunks, into said lower refuel end of said ODD reactor chamber, repeatedly, at refuel time intervals so that said ODD reactor chamber is largely filled with a bed of said coal chunks, and so that said coal chunks move through said ODD reactor chamber toward said upper gas outlet end, and pass into the connected upper gas outlet end of said coke reaction chamber, to create a bed of hot coke chunks within said coke reaction chamber; whereby a flow of coal chunks, and associated coal volatile matter, is created, passing through said ODD reactor chamber; an ash removal mechanism means for sealably transferring an ash removal quantity of coal ashes, from said lower ash removal end of said coke reaction chamber, into said ash receiver, periodically, at ash removal time intervals; wherein the depth, of said ODD reaction chamber, is sufficient to contain at least three refuel quantities within said reaction chamber; wherein the depth of said coke reaction chamber, between said ash removal mechanism and said upper gas outlet, is sufficient to contain more than six layers of coke chunks, within said coke reaction chamber, in addition to a layer of ashes above the ash removal mechanism; hot gas generator means for creating a flow of hot oxygen-containing gas, through said bed of coal chunks, within said ODD reactor chamber, said gas comprising, a portion of diluent gases, such as nitrogen, or carbon dioxide, or steam, or combinations thereof, and a portion of oxygen, so that the oxygen mol fraction in said hot oxygen containing gas is less than the oxygen mol fraction in air at sea level, and so that the flow of oxygen, into said ODD reactor chamber, is less than stoichiometric relative to the flow of coal volatile matter, into said ODD reactor chamber, and further so that the temperature of said hot, oxygen containing gas at least equals the rapid devolitization temperature of said coal chunks; wherein said flow of hot oxygen containing gas is connected into the gas inlet end of the said ODD reactor chamber; whereby oxidative, destructive, distillation of the coal chunks, within said ODD reactor chamber, takes place, and creates two coal derived products, a hot devolatilized coke, which enters the connected upper gas outlet end of said coke reactor, and a partially oxidized volatile matter product, which flows into said connected ODD overfire burner chamber accompanied by the diluent portions of said hot oxygen containing gas; ODD overfire burner compressed air supply means for supplying a flow of compressed air, from said source of compressed air, into said ODD overfire burner; whereby a flowing, and ignitable, fuel air mixture is created within said ODD overfire burner and can be ignited by said igniter means and burned to hot burned gases; coke bed depth sensor means for sensing the depth of the coal chunk bed, above the ash layer, in said coke reaction chamber; coke bed depth control means, responsive to said coke bed depth sensor means, and operative to adjust said refuel time interval, of said refuel mechanism, so that the coke fuel bed depth, within said coke reaction chamber, exceeds six layers of coal chunks, and remains below the gas outlet end of said coke reaction chamber, by increasing the length of said refuel time interval when the coke bed depth approaches the gas outlet end, and by decreasing the length of said refuel time interval when the coke bed depth approaches six layers of coal chunks; wherein said coke bed depth sensor and control means can be hand sensor and control means or automatic sensor and control means, or combinations of hand and automatic sensor and control means; a coke burner air supply means for creating a flow of primary compressed air, from said source of compressed air, into said lower gas inlet end of said coke reaction chamber, and through said bed of hot coke chunks therein, so that: said hot coke reacts with oxygen in the primary air, and is gasified into gaseous carbon monoxide and carbon dioxide and solid ashes, and said coal chunks and ashes move down through said coke reaction chamber, toward said ash removal mechanism, and in a direction opposite to the direction of primary air flow; and said ashes are essentially fully separated from said coke and collect near the lower gas inlet end of said coke reaction chamber; and said carbon monoxide and carbon dioxide gases, together with diluent nitrogen gas from said primary air, flow from said upper gas outlet end of said coke reaction chamber and into said connected carbon monoxide overfire burner; carbon monoxide overfire burner compressed air supply means for supplying a flow of compressed air from said source of compressed air into said carbon monoxide overfire burner; whereby a flow of ignitable fuel air mixture is created within said carbon monoxide overfire burner and can be ignited by said igniter means and burned to hot burned gases; said hot burned gases from said ODD overfire burner and from said carbon monoxide overfire burner flow into said connected receiver of hot burned gases; ash bed depth sensor means for sensing the depth of the ashes, collected at the lower ash removal end of the coke reaction chamber, above the ash removal mechanism; ash bed depth control means, responsive to said ash bed depth sensor means, and operative to adjust said ash removal time interval, of said ash removal mechanism, so that; the ash volume within said coke reaction chamber, and outside said ash removal mechanism, always exceeds the ash removal volume of said ash removal mechanism; and further so that; the ash volume within said coke reaction chamber, and outside said ash removal mechanism, is preferably no greater than three times the ash removal volume of said ash removal mechanism; wherein said ash bed depth sensor and control means can be hand sensor and control means, or automatic sensor and control means, or combinations of hand and automatic sensor and control means; whereby a layer of ashes is always present between said ash removal mechanism and said hot burning coke.
 2. A mixed fuel coal burner as described in claim 1: wherein none of said coal chunks will pass through a one half inch screen; wherein said receiver of hot burned gases is the inlet to the expander turbine portion of a gas turbine engine; wherein said source of compressed air is a portion of the compressor discharge air from the compressor portion of said gas turbine engine.
 3. A mixed fuel coal burner as described in claim 2: wherein said hot gas generator means comprises: a source of gas or liquid fuel at a pressure at least equal to the pressure of said source of compressed air; an ODD burner chamber and enclosure comprising two inlets, an outlet end, and an igniter means; an ODD burner fuel meter means for creating a flow of fuel from said source of gas or liquid fuel, into one said inlet of said ODD burner chamber; an ODD burner air supply means for creating a flow of compressed air, from said source of compressed air into the other said inlet of said ODD burner chamber; wherein the ratio of said flow of compressed air to said flow of fuel is within the spark ignitable limits; whereby ignition and burning of said fuel and air occurs within said ODD burner chamber and creates a flow of hot burned gases through said outlet of said ODD burner chamber; an ODD mixer chamber and enclosure comprising two inlets and an outlet, one of said inlets connecting to the outlet of said ODD burner chamber, the outlet of said mixer chamber connecting to said gas inlet of said ODD reaction chamber; an ODD mixer air supply means for creating a flow of compressed air from said source of compressed air into the other said inlet of said ODD mixer chamber; whereby said hot burned gas, from said ODD burner chamber, is mixed with air, in said ODD mixer chamber, to create a hot, oxygen containing gas, which flows into and through said connected ODD reaction chamber, to cause oxidative, destructive, distillation of the coal volatile matter to take place therein; wherein the ratio of the flow of hot burned gases, from said ODD burner, to mixer air flow, into said ODD mixer, is set to create an oxygen mol fraction, within the hot oxygen containing mixer exit gases, less than the mol fraction of oxygen in air at sea level; and further wherein the flow of oxygen, via said hot oxygen containing gas, into said ODD reaction chamber is less than stoichiometric relative to the flow of coal volatile matter into said ODD reaction chamber; wherein said overfire burner chamber, and enclosure, further comprises a supplementary overfire burner chamber, and igniter means; and further comprising supplementary fuel air mixture generator means for creating a flow of supplementary, ignitable, fuel air mixture into said supplementary overfire burner chamber, and comprising: a generator chamber comprising two separate generator inlets, and a generator outlet connecting into said supplementary overfire burner chamber; a supplementary fuel meter means for creating a flow of fuel, from said source of gas or liquid fuel, into one said generator inlet; a supplementary air supply means for creating a flow of compressed air, from said source of compressed air, into the other said generator inlet; wherein the fuel in air mixture, thusly created within said generator chamber, is ignitable, and flows into said supplementary overfire burner chamber, and is ignited and burned therein to burned gases; and further comprising: a speed sensor means for sensing gas turbine engine shaft rotational speed; supplementary fuel air mixture control means for controlling the rate of flow of supplementary fuel air mixture, into said supplementary overfire burner chamber, responsive to said speed sensor means, and operative upon said supplementary fuel air mixture generator means, so that, said flow of supplementary fuel air mixture is increased, when gas turbine engine shaft speed is less than a preset value, and so that said flow of supplementary fuel air mixture is decreased, when gas turbine engine shaft speed is greater than said preset value; whereby gas turbine engine shaft speed is maintained within a narrow range about said preset value; a load sensor means for sensing gas turbine engine load; coal control means for controlling the rate of coal burning in said mixed fuel coal burner, responsive to said load sensor means, and operative upon: said hot oxygen containing gas generator means; said coke burner air supply means; said ODD overfire burner compressed air supply means; said carbon monoxide overfire burner compressed air supply means; so that: the flow rate of hot oxygen containing gas into said ODD reaction chamber, and the flow rate of primary air into said coke burner and the flow rate of compressed air into said ODD overfire burner, and the flow rate of compressed air into said carbon monoxide overfire burner, are all changed in proportion to gas turbine engine load; whereby the rate of coal burning is controlled, by said coal control means, so as to be proportional to gas turbine engine load; comparator means for comparing the rate of coal burning, as controlled by said coal control means to the rate of supplementary fuel air mixture burning, as controlled by said supplementary air fuel mixture control means, to determine the ratio of coal energy release rate divided by the supplementary air fuel mixture energy release rate, and to compare this ratio to a preset value for this ratio, and operative upon said coal control means, to increase said coal burning rate when said determined ratio is less than said preset value, and to decrease said coal burning rate when said determined ratio exceeds said preset value.
 4. A mixed fuel coal burner, as described in claim 3: wherein said compressed air supply means are positive displacement air meters.
 5. A mixed fuel coal burner, as described in claim 1: wherein said receiver of hot burned gases is a furnace; wherein said hot gas generator means comprises: a source of gas or liquid fuel at a pressure at least equal to the pressure of said source of compressed air; an ODD burner chamber and enclosure, comprising two inlets, an outlet end, and an igniter means; an ODD burner fuel meter means for creating a flow of fuel, from said source of gas or liquid fuel, into one said inlet of said ODD burner chamber; an ODD burner air supply means for creating a flow of compressed air, from said source of compressed air into the other said inlet of said ODD burner chamber; wherein the ratio of said flow of compressed air to said flow of fuel is within the spark ignitable limits; whereby ignition and burning of said fuel and air occurs within said ODD burner chamber and creates a flow of hot burned gases through said outlet of said ODD burner chamber; an ODD mixer chamber and enclosure comprising two inlets and an outlet, one of said inlets connecting to the outlet of said ODD burner chamber, the outlet of said mixer chamber connecting to said gas inlet of said ODD reaction chamber; an ODD mixer air supply means for creating a flow of compressed air from said source of compressed air into the other said inlet of said ODD mixer chamber; whereby said hot burned gas, from said ODD burner chamber, is mixed with air, in said ODD mixer chamber, to create a hot oxygen containing gas, which flows into and through said connected ODD reaction chamber, to cause oxidative, destructive, distillation of the coal volatile matter to take place therein; wherein the ratio of the flow of hot burned gases, from said ODD burner, to mixer air flow, into said ODD mixer, is set to create an oxygen mol fraction, within the hot oxygen containing mixer exit gases, less than the mol fraction of oxygen in air at sea level; and further wherein the flow oxygen, via said hot oxygen containing gas, into said ODD reaction is less than stoichiometric relative to the flow of coal volatile matter into said ODD reaction chamber.
 6. A mixed fuel coal burner is described in claim 5: wherein said overfire burner chamber, and enclosure, further comprises a supplementary overfire burner chamber, and igniter means; and further comprising supplementary fuel in air mixture generator means for creating a flow of supplementary, ignitable, fuel air mixture into said supplementary overfire burner chamber, and comprising: a generator chamber comprising two separate generator inlets, and a generator outlet connecting into said supplementary overfire burner chamber; a supplementary fuel meter means for creating a flow of fuel, from said source, of gas or liquid fuel, into one said generator inlet; a supplementary air supply means for creating a flow of compressed air, from said source of compressed air, into the other said generator inlet; wherein the fuel in air mixture, thusly created within said generator chamber, is ignitable, and flows into said supplementary overfire burner chamber, and is ignited and burned therein to burned gases.
 7. A coal reactor for transforming coals, containing volatile matter, into two different fuel products, a clean burning gas fuel, derived from the coal volatile matter, and a solid coke fuel, and comprising: a source of coal chunks containing volatile matter; a coke receiver; a receiver of volatile matter derived fuel; an ODD reaction chamber and enclosure, and comprising a lower refuel end, a gas inlet near said refuel end, and an upper gas and coke outlet end; said gas and coke outlet end, of said ODD reaction chamber, connecting into said receiver of volatile matter derived fuel, and also connecting separately into said coke receiver; a refuel mechanism means for transferring a refuel quantity of coal chunks, from said source of coal chunks, into the lower refuel end of said ODD reaction chamber, repeatedly, so that said ODD reaction chamber is largely filled with a bed of coal chunks, and so that said coal chunks move through said ODD reaction chamber toward said upper gas and coke outlet end, and pass into the connected coke receiver; whereby a flow of coal chunks, and associated coal volatile matter, is created passing through said ODD reaction chamber; hot gas generator means for creating a flow of hot, oxygen containing gas, through said bed of coal chunks, within said ODD reaction chamber, said hot gas comprising, a portion of diluent gases, such as nitrogen, or carbon dioxide, of steam, or combinations thereof, and a portion of oxygen, so that the oxygen mol fraction in said hot oxygen containing gas is less than the oxygen mol fraction in air at sea level, and so that the flow of oxygen, into said ODD reaction chamber, is less than stoichiometric relative to the flow of coal volatile matter, into said ODD reaction chamber, and further so that the temperature of said hot, oxygen containing gas at least equals the rapid devolitization temperature of said coal chunks; wherein said flow of hot oxygen containing gas is connected into the gas inlet end of said ODD reaction chamber; whereby oxidative destructive distillation, of the coal chunks within said ODD reaction chamber, takes place, and creates two coal derived products, a devolatilized solid coke product, which passes into said connected coke receiver and a partially oxidized volatile matter product which flows into said connected receiver of volatile matter derived fuel accompanied by the diluent portions of said hot, oxygen containing gas.
 8. A coal reactor as described in claim 7, wherein said hot gas generator means comprises: a source of compressed air at a pressure greater than atmospheric; wherein said hot gas generator means comprises: a source of gas or liquid fuel at a pressure at least equal to the pressure of said source of compressed air; an ODD burner chamber and enclosure, comprising two inlets, an outlet end, and an igniter means; an ODD burner fuel meter means for creating a flow of fuel, from said source of gas or liquid fuel, into one said inlet of said ODD burner chamber; an ODD burner air supply means for creating a flow of compressed air, from said source of compressed air into the other said inlet of said ODD burner chamber; wherein the ratio of said flow of compressed air to said flow of fuel is within the spark ignitable limits; whereby ignition and burning of said fuel and air occurs within said ODD burner chamber and creates a flow of hot burned gases through said outlet of said ODD burner chamber; an ODD mixer chamber and enclosure comprising two inlets and an outlet, one of said inlets connecting to the outlet of said ODD burner chamber, the outlet of said mixer chamber connecting to said gas inlet of said ODD reaction chamber; an ODD mixer air supply means for creating a flow of compressed air from said source of compressed air into the other said inlet of said ODD mixer chamber; whereby said hot burned gas, from said ODD burner chamber, is mixed with air, in said ODD mixer chamber, to create a hot, oxygen containing gas, which flows into and through said connected ODD reaction chamber, to cause oxidative, destructive, distillation of the coal volatile matter to take place therein; wherein the ratio of the flow of hot burned gases, from said ODD burner, to mixer air flow, into said ODD mixer, is set to create an oxygen mol fraction, within the hot oxygen containing mixer exit gases, less than the mol fraction of oxygen in air at sea level; and further wherein the flow of oxygen, via said hot oxygen containing gas, into said ODD reaction chamber is less than stoichiometric relative to the flow of coal volatile matter into said ODD reaction chamber.
 9. A coal reactor as described in claim 8: wherein none of said coal chunks will pass through a one half inch screen; wherein said source of compressed air is a portion of the compressor discharge air from the compressor portion of a gas turbine engine; and further comprising: an ODD overfire burner chamber and enclosure, and comprising: a fuel inlet, a compressed air inlet, a burned gas outlet, and igniter means for igniting fuel in air mixtures within said overfire burner chamber; wherein said refuel mechanism means for transferring coal into the refuel end of the ODD reaction chamber, thusly transfers a refuel quantity of coal Sealably and repeatedly, at refuel time intervals; wherein said receiver of volatile matter derived fuels is said ODD overfire burner and chamber, whose fuel inlet is connected to said upper gas and coke outlet end of said ODD reaction chamber; ODD overfire burner compressed air supply means for supplying a flow of compressed air, from said source of compressed air, into said compressed air inlet of said ODD overfire burner chamber; wherein said burned gas outlet of said ODD overfire burner chamber, is connected to the inlet of the expander turbine portion of a gas turbine engine; whereby a flowing and ignitable fuel air mixture is created, within said ODD overfire burner, and can be ignited by said igniter means, and burned to hot burned gases, which flow into the inlet of the expander turbine of said gas turbine engine; a coke collector at atmospheric pressure; wherein said coke receiver comprises a coke chamber and enclosure comprising a lower coke removal end, and an upper coke inlet end, said coke inlet connecting to said upper gas and coke outlet end of said ODD reaction chamber; a coke removal mechanism means for sealably transferring a coke removal quantity of coke chunks, from said lower coke removal end of said coke receiver, into said coke collector, periodically, at coke removal time intervals; coke depth sensor means for sensing the depth of the coal chunks within said coke chamber; coke depth control means, responsive to said coke depth sensor means, and operative to adjust said coke removal time interval, so that the coke depth remains below said coke inlet end, by decreasing said coke removal time interval when coke depth approaches the upper coke inlet end; wherein said coke depth sensor and control means can be hand sensor or control means, or automatic sensor and control means, or combinations of hand and automatic sensor and control means.
 10. A process for transforming coal chunks, containing volatile matter, into two separate fuel products, a solid coke fuel, and a partially oxidized volatile matter derived fuel, and comprising the following steps: passing coal chunks through an enclosed ODD reactor; passing hot, oxygen containing gases concurrently through said ODD reactor; wherein the molal oxygen concentration, in said hot oxygen containing gases, is less than the molal oxygen concentration in air at sea level; wherein the temperature of said hot oxygen containing gas exceeds the rapid devolatilization temperature of the coal; wherein the ratio of oxygen, passing through the ODD reactor, to coal volatile matter, concurrently passing through said ODD reactor, is less than stoichiometric, for full burnup of said volatile matter to carbon dioxide and water vapor; whereby oxidative destructive distillation of the coal volatile matter takes place inside the ODD reactor, and transforms said coal chunks into a partially oxidized volatile matter derived fuel, and hot solid devolatilized coke fuel chunks; passing said volatile matter derived fuel out of said ODD reactor, and into a receiver of this fuel product; passing said hot solid devolatilized coke fuel chunks out of said ODD reactor, and into a receiver of this coke fuel product.
 11. A process for transforming coal chunks, containing volatile matter, into two separate fuel products, as described in claim 10: wherein the hot oxygen containing gases are generated by the following process steps: passing burner air, and a gas or liquid fuel, concurrently, through an ODD burner enclosure, in spark ignitable proportions, to create a fuel in air mixture; igniting said fuel in air mixture to create a hot burned gas; passing said hot burned gas, and ODD mixer air, concurrently, through a mixer enclosure, to create a hot oxygen containing gas.
 12. A process for the clean burning of coal chunks, containing volatile matter, and without ash carryover into the resulting burned gases, and comprising the following steps, in addition to the process steps described in claim 11; passing said volatile matter derived fuel, from said ODD reactor, through an ODD overfire burner enclosure as a receiver of volatile matter derived fuel; passing ODD overfire air concurrently through said ODD overfire burner enclosure, to create a fuel in air mixture; wherein the ratio of said ODD overfire air flow to said volatile matter derived fuel flow, of said fuel in air mixture, within said ODD overfire burner, lies within the spark ignitable limits; igniting said fuel in air mixture, within said ODD overfire burner enclosure, to create an ODD overfire burned gas; passing said ODD overfire burned gas, out of said ODD overfire burner enclosure, and into a receiver of hot burned gases; passing said hot solid devolatilized coke fuel chunks, from said ODD reactor, into the upper end of a coke reactor chamber and enclosure as a receiver of coke fuel product; passing primary air into the lower end of said coke reactor chamber; whereby said hot coke fuel chunks react with oxygen, in said primary air, and with the carbon dioxide, formed by said reaction of oxygen with said hot coke fuel, and said hot coke fuel is gasified into carbon monoxide, and carbon dioxide, and residual solid ashes, and said coke fuel chunks, and ashes, move downward through said coke reaction chamber, in a direction opposite to the direction of flow of said primary air, and said residual ashes collect at the lower end of said coke reaction chamber; maintaining a depth of coke fuel chunks, within said coke reaction chamber, sufficient, that the molal ratio of coke fuel carbon, thusly gasified into carbon dioxide and carbon monoxide, to primary air supplied, preferable exceeds a value of 0.35; passing said collected ashes, from said lower end of said coke reaction chamber, into a receiver of ashes; passing said carbon monoxide, and carbon dioxide, together with unreacted portions of said primary air, through a carbon monoxide overfire burner enclosure; passing carbon monoxide overfire air concurrently through said carbon monoxide overfire burner enclosure to create a fuel in air mixture; wherein the ratio of said carbon monoxide overfire air flow, to said flow of carbon monoxide and carbon dioxide and unreacted portions of said primary air, within said carbon monoxide overfire burner, lies within the spark ignitable limits; igniting said fuel in air mixture within said carbon monoxide overfire burner enclosure to create a carbon monoxide overfire burned gas; passing said carbon monoxide overfire burned gas out of said carbon monoxide overfire burner enclosure and into said receiver of hot burned gases.
 13. A mixed fuel coal burner, for the clean and controllable burning of coals containing volatile matter, and without ash being carried over with the burned gases leaving the burner, and comprising: a source of coal chunks containing volatile matter, and at atmospheric pressure; a source of compressed air at a pressure greater than atmospheric; an ash receiver at atmospheric pressure; a receiver of hot burned gases; an ODD reactor chamber and enclosure, and comprising a lower refuel end, a gas inlet near said refuel end, and an upper gas and coke outlet end; a coke reaction chamber and enclosure, and comprising a lower ash removal end, a gas inlet near said ash removal end, and an upper gas outlet end; said gas and coke outlet end of said ODD reactor chamber connecting into said gas outlet end of said coke reaction chamber; an overfire burner enclosure comprising at least two overfire burner chambers: an ODD overfire burner chamber, connected to said upper gas and coke outlet end of said ODD reactor chamber; and a carbon monoxide overfire burner chamber connected to said upper gas outlet end of said coke reaction chamber; and further comprising igniter means for igniting fuel in air mixtures within said overfire burner chambers; and further comprising a gas outlet into said receiver of hot burned gases; a refuel mechanism means for sealably transferring a refuel quantity of coal chunks, from said source of coal chunks, into said lower refuel end of said ODD reactor chamber, repeatedly, at refuel time intervals, so that said ODD reactor chamber is largely filled with a bed of said coal chunks, and so that said coal chunks move through said ODD reactor chamber toward said upper gas outlet end, and pass into the connected upper gas outlet end of said coke reaction chamber, to create a bed of hot coke chunks within said coke reaction chamber; whereby a flow of coal chunks, and associated coal volatile matter, is created, passing through said ODD reactor chamber; an ash removal mechanism means for sealably transferring an ash removal quantity of coal ashes, from said lower ash removal end of said coke reaction chamber, into said ash receiver, periodically, at ash removal time intervals; wherein the depth, of said ODD reactor chamber, is sufficient to contain at least three refuel quantities within said reactor chamber; wherein the depth of said coke reaction chamber, between said ash removal mechanism and said upper gas outlet, is sufficient to contain more than six layers of coke chunks, within said coke reaction chamber, in addition to a layer of ashes above the ash removal mechanism; hot gas generator means for creating a flow of hot molecular oxygen-containing gas, through said bed of coal chunks, within said ODD reactor chamber, said hot gas comprising, a portion of diluent gases, such as nitrogen, or carbon dioxide, or steam, or combinations thereof, and a portion of molecular oxygen, so that the molecular oxygen mol fraction in said hot molecular oxygen containing gas is less than the molecular oxygen mol fraction in air at sea level, and so that the flow of molecular oxygen, into said ODD reactor chamber, is less than stoichiometric relative to the flow of coal volatile matter, into said ODD reactor chamber, and further so that the temperature of said hot molecular oxygen containing gas at least equals the rapid devolatilization temperature of said coal chunks; wherein said flow of hot molecular oxygen containing gas is connected into the gas inlet end of the said ODD reactor chamber; whereby oxidative, destructive, distillation of the coal chunks, within said ODD reactor chamber, takes place, and creates two coal derived products, a hot devolatilized coke, which enters the connected upper gas outlet end of said coke reaction chamber, and a partially oxidized volatile matter product, which flows into said connected ODD overfire burner chamber accompanied by the diluent portions of said hot molecular oxygen containing gas; ODD overfire burner compressed air supply means for supplying a flow of compressed air, from said source of compressed air, into said ODD overfire burner; whereby a flowing, and ignitable, fuel air mixture is created within said ODD overfire burner and can be ignited by said igniter means and burned to hot burned gases; coke bed depth sensor means for sensing the depth of the coke chunk bed, above the ash layer, in said coke reaction chamber; coke bed depth control means, responsive to said coke bed depth sensor means, and operative to adjust said refuel time interval, of said refuel mechanism, so that the coke fuel bed depth, within said coke reaction chamber, exceeds six layers of coal chunks, and remains below the gas outlet end of said coke reaction chamber, by increasing the length of said refuel time interval when the coke bed depth approaches the gas outlet end, and by decreasing the length of said refuel time interval when the coke bed depth approaches six layers of coal chunks; wherein said coke bed depth sensor and control means can be hand sensor and control means or automatic sensor and control means, or combinations of hand and automatic sensor and control means; a coke reaction chamber air supply means for creating a flow of primary compressed air, from said source of compressed air, into said lower gas inlet end of said coke reaction chamber, and through said bed of hot coke chunks therein, so that: said hot coke reacts with molecular oxygen in the primary air, and is gasified into gaseous carbon monoxide and carbon dioxide and solid ashes, and said coal chunks and ashes move down through said coke reaction chamber, toward said ash removal mechanism, and in a direction opposite to the direction of primary air flow; and said ashes are essentially fully separated from said coke and collect near the lower gas inlet end of said coke reaction chamber; and said carbon monoxide and carbon dioxide gases, together with diluent nitrogen gas and from said primary air, flow from said upper gas outlet end of said coke reaction chamber and into said connected carbon monoxide overfire burner; carbon monoxide overfire burner compressed air supply means for supplying a flow of compressed air from said source of compressed air into said carbon monoxide overfire burner; whereby a flow of ignitable fuel air mixture is created within said carbon monoxide overfire burner and can be ignited by said igniter means and burned to hot burned gases; said hot burned gases from said ODD overfire burner and from said carbon monoxide overfire burner flow into said connected receiver of hot burned gases; ash bed depth sensor means for sensing the depth of the ashes, collected at the lower ash removal end of the coke reaction chamber, above the ash removal mechanism, ash bed depth control means, responsive to ash bed depth sensor means, and operative to adjust said ash removal time interval, of said ash removal mechanism, so that: the ash volume within said coke reaction chamber, and outside the ash removal mechanism, always exceeds the ash removal volume of said ash removal mechanism; and further so that: the ash volume within said coke reaction chamber, and outside said ash removal mechanism, is preferably no greater than three times the ash removal volume of said ash removal mechanism; wherein said ash bed depth sensor and control means can be hand sensor and control means, or automatic sensor and control means, or combinations of hand and automatic sensor and control means; whereby a layer of ashes is always present between said ash removal mechanism and said hot burning coke.
 14. A mixed fuel coal burner as described in claim 13: wherein none of said coal chunks will pass through a one half inch screen; wherein said receiver of hot burned gases is the inlet to the expander turbine portion of a gas turbine engine; wherein said source of compressed air is a portion of the compressor discharge air from the compressor portion of said gas turbine engine.
 15. A mixed fuel coal burner as described in claim 14: wherein said hot gas generator means comprises; a source of gas or liquid fuel at a pressure at least equal to the pressure of said source of compressed air; an ODD burner chamber and enclosure comprising two inlets, an outlet end, and an igniter means; an ODD burner fuel meter means for creating a flow of fuel from said source of gas or liquid fuel, into one said inlet of said ODD burner chamber; an ODD burner air supply means for creating a flow of compressed air, from said source of compressed air into the other said inlet of said ODD burner chamber; wherein the ratio of said flow of compressed air to said flow of fuel is within the spark ignitable limits; whereby ignition and burning of said fuel and air occurs within said ODD burner chamber and creates a flow of hot burned gases through said outlet of said ODD burner chamber; an ODD mixer chamber and enclosure comprising two inlets and an outlet, one of said inlets connecting to the outlet of said ODD burner chamber, the outlet of said mixer chamber connecting to said gas inlet of said ODD reactor chamber; an ODD mixer air supply means for creating a flow of compressed air from said source of compressed air into the other said inlet of said ODD mixer chamber; whereby said hot burned gas, from said ODD burner chamber, is mixed with air, in said ODD mixer chamber, to create a hot, molecular oxygen containing gas, which flows into and through said connected ODD reactor chamber, to cause oxidative, destructive, distillation of the coal volatile matter to take place therein; wherein the ratio of the flow of hot burned gases, from said ODD burner, to mixer air flow, into said ODD mixer, is set to create a molecular oxygen mol fraction, within the hot molecular oxygen containing mixer exit gases, less than the mol fraction of molecular oxygen in air at sea level; and further wherein the flow of molecular oxygen, via said hot molecular oxygen containing gas, into said ODD reactor chamber is less than stoichiometric relative to the flow of coal volatile matter into said ODD reactor chamber; wherein said overfire burner chamber, and enclosure, further comprises a supplementary overfire burner chamber, and igniter means; and further comprising supplementary fuel air mixture generator means for creating a flow of supplementary, ignitable, fuel air mixture into said supplementary overfire burner chamber, and comprising: a generator chamber comprising two separator generator inlets, and a generator outlet connecting into said supplementary overfire burner chamber; a supplementary fuel meter means for creating a flow of fuel, from said source of gas or liquid fuel, into one said generator inlet; a supplementary air supply means for creating a flow of compressed air, from said source of compressed air, into the other said generator inlet; wherein the fuel in air mixture, thusly created within said generator chamber, is ignitable, and flows into said supplementary overfire burner chamber, and is ignited and burned therein to burned gases; and further comprising: a speed sensor means for sensing gas turbine engine shaft rotational speed; supplementary air fuel mixture control means for controlling the rate of flow of supplementary fuel air mixture, into said supplementary overfire burner chamber, responsive to said speed sensor means, and operative upon said supplementary fuel air mixture generator means, so that, said flow of supplementary fuel air mixture is increased, when gas turbine engine shaft speed is less than a preset value, and so that said flow of supplementary fuel air mixture is decreased, when gas turbine engine shaft speed is greater than said preset value; whereby gas turbine engine shaft speed is maintained within a narrow range about said preset value; a load sensor means for sensing gas turbine engine load; coal control means for controlling the rate of coal burning in said mixed fuel coal burner, responsive to said load sensor means, and operative upon: said hot molecular oxygen containing gas generator means, said coke reaction chamber air supply means; said ODD overfire burner compressed air supply means; said carbon monoxide overfire burner chamber air supply means; so that; the flow rate of hot molecular oxygen containing gas into said ODD reactor chamber, and the flow rate of primary air into said coke reaction chamber, and the flow rate of compressed air into said ODD overfire burner, and the flow rate of compressed air into said carbon monoxide overfire burner, are all changed in proportion to gas turbine engine load; whereby the rate of coal burning is controlled, by said coal control means, so as to be proportional to gas turbine engine load; comparator means for comparing the rate of coal burning, as controlled by said coal control means, to the rate of supplementary air fuel mixture burning, as controlled by said supplementary air fuel mixture control means, to determine the ratio of coal energy release rate divided by the supplementary air fuel mixture energy release rate, and to compare this ratio to a preset value for this ratio, and operative upon said control means, to increase said coal burning rate when said determined ratio is less than said preset value, and to decrease said coal burning rate when said determined ratio exceeds said preset value.
 16. A mixed fuel coal burner, as described in claim 15: wherein said compressed air supply means are positive displacement air meters.
 17. A mixed fuel coal burner, as described in claim 13, wherein said receiver of hot burned gases is a furnace; wherein said hot gas generator means comprises: a source of gas or liquid fuel at a pressure at least equal to the pressure of said source of compressed air; an ODD burner chamber and enclosure, comprising two inlets, an outlet end, and an igniter means; an ODD burner fuel meter means for creating a flow of fuel, from said source of gas or liquid fuel, into one said inlet of said ODD burner chamber; an ODD burner air supply means for creating a flow of compressed air, from said source of compressed air into the other said inlet of said ODD burner chamber; wherein the ratio of said flow of compressed air to said flow of fuel is within the spark ignitable limits; whereby ignition and burning of said fuel and air occurs within said ODD burner chamber and creates a flow of hot burned gases through said outlet of said ODD burner chamber; an ODD mixer chamber and enclosure comprising two inlets and an outlet, one of said inlets connecting to the outlet of said ODD burner chamber, the outlet of said mixer chamber connecting to said gas inlet of said ODD reactor chamber; an ODD mixer air supply means for creating a flow of compressed air from said source of compressed air into the other said inlet of said ODD mixer chamber; whereby said hot burned gas, from said ODD burner chamber, is mixed with air, in said ODD mixer chamber, to create a hot molecular oxygen containing gas, which flows into and through said connected ODD reactor chamber, to cause oxidative destructive, distillation of the coal volatile matter to take place therein; wherein the ratio of the flow of hot burned gases, from said ODD burner, to mixer air flow, into said ODD mixer, is set to create a molecular oxygen mol fraction, within the hot molecular oxygen containing mixer exit gases, less than the mol fraction of molecular oxygen in air at sea level; and further wherein the flow of molecular oxygen, via said hot molecular oxygen containing gas, into said ODD reactor chamber is less than stoichiometric relative to the flow of coal volatile matter into said ODD reactor chamber.
 18. A mixed fuel coal burner as described in claim 17: wherein said overfire burner chamber, and enclosure, further comprises a supplementary overfire burner chamber, and igniter means; and further comprising supplementary fuel in air mixture generator means for creating a flow of supplementary, ignitable, fuel air mixture into said supplementary overfire burner chamber, and comprising: a generator chamber comprising two separate generator inlets, and a generator outlet connecting into said supplementary overfire burner chamber; a supplementary fuel meter means for creating a flow of fuel, from said source of gas or liquid fuel, into one said generator inlet; a supplementary air supply means for creating a flow of compressed air, from said source of compressed air, into the other said generator inlet; wherein the fuel in air mixture, thusly created within said generator chamber, is ignitable, and flows into said supplementary overfire burner chamber, and is ignited and burned therein to burned gases. 